KR101278638B1 - Smart energy management system and control method thereof - Google Patents

Abstract

PURPOSE: A smart energy management system and a control method thereof are provided to automatically adjust an indoor temperature, humidity, and ventilation according to the outdoor weather, thereby saving energy. CONSTITUTION: An energy management module(36) includes an Ethernet model(40), memory(42), monitoring unit(44), control unit(46), analysis unit(48), and control module(50). The memory saves outdoor weather conditions, indoor weather conditions, a temperature and humidity set by the analysis unit, adequate electricity consumption analyzed by the analysis unit, a weather forecast cast by the internet, and power supply alarm status. The monitoring unit collects the information on the status of equipment operation and provides the information to the control module. The control unit transmits the data about the temperature and the humidity sent by the control module to equipment, and controls the operation of equipment in preparation for peak power. The analysis unit sets a temperature and humidity for equipment, provides the analysis information for peak operation to the control module considering the operation status of equipment provided by the monitoring unit if electricity consumption is over the predetermined adequate amount, and determines an adequate electricity consumption by applying at least one of the weather forecast and the power supply alarm status saved in the memory. A management server(34) provides information including the weather forecast supplied by a Korea Meteorological Administration server(20) or the power supply alarm status supplied by a KOSEP server(32) corresponding to casting through an internet network. The energy management module is connected to an electricity sensor(18), weather sensor(20), and indoor sensor(22), and connected to the Korea Meteorological Administration server, KOSEP sever, and management server through an internet network. [Reference numerals] (10) Air conditioner; (12) Air conditioner; (14) Lighting device; (16) Power supply device; (18) Electricity sensor; (20) Korea Meteorological Administration server(temperature and humidity); (22) Indoor sensor( temperature, humidity, the amount of CO_2); (30) KMA server; (32) KOSEP server; (34) Management server; (40) Ethernet model; (42) Memory; (44) Monitoring unit; (46) Control unit; (48) Analysis unit; (50) Control module; (AA) Internet network

Description

Smart energy management system and its control method {SMART ENERGY MANAGEMENT SYSTEM AND CONTROL METHOD THEREOF}

The present invention relates to a smart energy management system, and more particularly, to a smart energy management system and a control method for controlling equipment in a building according to weather conditions and performing peak operation for energy saving.

As social development advances, facilities such as buildings gradually increase in size.

As buildings become larger, automation and intelligence systems are required to be introduced, and the application of energy management systems in line with government energy saving policies is required.

The energy management system stores configuration information, performance information, operator information, failure information and various detailed information of all equipment in a facility such as a building that needs control, and checks whether there is an abnormality of the equipment, and sends a message according to the abnormality of the equipment. It needs to be configured to provide it.

In addition, the energy management system should be configured to control the equipment by receiving the control command of the equipment based on the abnormality message, and should be designed to manage the facility without the operator always monitoring.

In addition, the energy management system needs to be implemented to automatically adjust the temperature and humidity of the room according to the external weather conditions.

In addition, the energy management system must be configured to efficiently manage the power usage to implement energy-saving operation.

Smart energy management system and its control method according to the present invention is to compare the outdoor weather conditions and indoor conditions to control the temperature and humidity and to control the operation of the air conditioner.

In addition, the smart energy management system and its control method according to the present invention is to analyze the power usage to perform the peak operation control when the preset appropriate power usage is exceeded to another purpose to save energy.

In addition, the smart energy management system and control method according to the present invention by calculating the appropriate power consumption by selectively referring to the expected weather or power supply and warning alarm state transmitted as casting data via the Internet to perform the peak operation control Saving is another purpose.

In addition, the smart energy management system and control method according to the present invention is to manage the outdoor weather conditions, the indoor state, the temperature and humidity set point and the power usage by the historical data to calculate the appropriate power usage to save energy another The purpose.

In addition, the smart energy management system and the control method according to the present invention is to further reduce the energy by restricting the supply of power in stages by classifying the equipment by stage power output adjustment or by type and location of the room. .

Smart energy management system according to the present invention, the equipment is driven by the power supplied; A power supply for supplying the power to the facilities; A power sensor for sensing power usage of the power supply device; A weather sensor for sensing an outdoor weather condition including temperature and humidity; An indoor sensor sensing an amount of CO ₂ and an indoor state including the temperature and humidity; An external server including at least one of a meteorological office server for providing an expected weather and a KEPCO server providing a power supply and demand alert state; And providing a temperature and humidity set point to the facilities by comparing the outdoor weather state and the indoor state, and analyzing the power usage to control the supply of the power supplied to the facility when the preset proper power usage is exceeded. And an energy management module configured to perform peak operation, connect to the external server via the Internet, and set the appropriate power usage by applying at least one of the expected weather and the power supply and demand warning state.

Here, the energy management module may control the circulation of indoor air by controlling a damper of an air conditioner included in the facilities when the amount of CO ₂ exceeds a preset set point.

The energy management module may include at least one or more of stepwise power output adjustment and operation control of a facility according to a predetermined schedule in the peak operation.

The schedule may restrict the supply of power in stages by dividing the facilities by types and by indoor locations.

The energy management module may manage the outdoor weather state, the indoor state, the temperature and humidity set point, and the power usage as history data, and the appropriate power usage may be set by further applying the history data.

And, the energy management module, Ethernet modem for connecting to the external server through the Internet; A memory for storing the outdoor weather condition, the indoor weather condition, the temperature and humidity set point, the appropriate power usage amount, the expected weather condition, and the power supply / demand alarm condition; A monitoring unit for providing information on operating states of the facilities; A control panel for transmitting the temperature and humidity set points to the facilities and controlling the operation of the facilities corresponding to the peak power; Compare the outdoor weather conditions with the indoor conditions to provide temperature and humidity set points to the facilities, and analyze the power usage to analyze analysis information for the peak operation with reference to the operation state when the preset appropriate power usage is exceeded. An analysis unit configured to set the appropriate power consumption by applying at least one of the expected weather and the power supply and demand alarm state; And receiving sensing signals of the meteorological sensor, the indoor sensor, and the power sensor and providing the sensing signals to the analysis unit, transferring the temperature and humidity set point provided from the analysis unit to the control panel, and operating the peak by the analysis information of the analysis unit. It may include; a control module for providing a control signal for controlling the control panel.

The control method of the smart energy management system according to the present invention comprises the steps of providing a temperature and humidity set point by comparing the indoor and outdoor temperature and humidity; Controlling the air conditioner damper when the amount of CO ₂ exceeds the set point to perform indoor ventilation; Sensing power usage of the facilities; Updating indoor and outdoor temperature and humidity, power consumption, and temperature and humidity set points with historical data; Receiving and storing at least one or more of the expected weather of the meteorological office server and the power supply and demand alert state of the KEPCO server through the Internet: and the appropriate power consumption calculated by applying at least one of the expected weather and the power supply and demand alert state. Analyzing the power usage as a reference to perform a peak operation to control the supply of the power supplied to the facility; may include.

The method may further include applying at least one of the expected weather and the power supply and demand warning state, and calculating and providing a predicted power usage with reference to the historical data.

The peak operation may include receiving monitoring information monitoring a state of operation of the facility; And adjusting the power output step by step when the power usage exceeds the appropriate usage amount.

In addition, the peak operation may be performed by controlling the operation of the facility in a step of restricting the supply of the power step by step by dividing the facilities by type and location of the room when the power usage exceeds the appropriate amount. Adjusting the power output.

Therefore, according to the present invention, the temperature and humidity control and ventilation of the room can be automatically performed according to the external weather conditions.

According to the present invention, the outdoor weather state, the indoor state, the temperature and humidity set point, and the power usage are managed as historical data, and the calculation is performed by selectively referring to the expected weather or power supply alert state transmitted as casting data through the Internet. Peak operation is performed to limit the use of power based on an appropriate power consumption, thereby saving energy.

In addition, according to the present invention, there is an effect of saving energy by restricting the supply of power step by step by adjusting the power output step by step or by classifying the facility by type and location of the room according to the peak operation.

1 is a block diagram showing a preferred embodiment of a smart energy management system according to the present invention.
2 is a flowchart illustrating a control method of a smart energy management system according to the present invention.
3 is a flowchart illustrating an example of peak operation.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the terminology used herein is for the purpose of description and should not be interpreted as limiting the scope of the present invention.

The embodiments described in the present specification and the configurations shown in the drawings are preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention and thus various equivalents and modifications Can be.

Referring to FIG. 1, the smart energy management system according to the present invention discloses a technology for controlling the amount of power used by facilities installed in facilities such as buildings and driven by being supplied with power.

Facilities that use electric power installed in facilities such as buildings may include an air conditioner 10, an air conditioner 12, a lighting device 14, and the like.

The air conditioner 10 is generally configured to include a temperature and humidity control for the entire building or a ventilation function corresponding to the amount of CO ₂ , and includes a cooling device and a heating device for temperature and humidity control.

The air conditioner 10 may be driven to maintain room temperature at approximately 26 ° C. to 28 ° C. in summer and at room temperature to 18 ° C. to 20 ° C. in winter. The room temperature may be varied according to the government's energy saving policy. And, the air conditioner 10 may be configured in plural in the building as needed.

As described above, the air conditioner 10 is configured to have an air conditioning function for the entire building. In contrast, the air conditioner 20 refers to an apparatus for individually cooling or heating each floor or arc of each floor.

The lighting device includes indoor or outdoor lightings and advertisement lights, and the lighting device can be switched by floor, door by floor, or by location of each floor. In the embodiment of FIG. 1, the lighting device 14 refers to a unit that is switched by floor, door, or location.

The air conditioner 10, the air conditioner 12, and the lighting device 14 are powered from the power supply device 16, and the power supply device 16 is connected to a lead wire (not shown) that receives external power. Refers to a device for distributing power by internal location.

The power supply device 16 is configured to sense power usage by the power sensor 18.

The embodiment according to the present invention senses the outdoor weather condition including the power sensor 18, temperature and humidity for sensing the power consumption in the building, that is, the power consumption supplied to and consumed by the power supply device 16 to each facility. It includes a weather sensor 20 and the indoor sensor 22 for sensing the indoor state including the temperature humidity and the amount of CO ₂ .

The meteorological sensor 20 includes at least a temperature sensor (not shown) for sensing an outdoor temperature and a humidity sensor (not shown) for sensing an outdoor humidity, and the indoor sensor 22 is configured to sense an indoor temperature. At least a temperature sensor (not shown), a humidity sensor (not shown) for sensing the humidity of the room and a CO ₂ sensor (not shown) for sensing the amount of CO _{2 in the} room. Here, the CO ₂ amount is meant the concentration of CO ₂ contained in the air.

In addition, the embodiment according to the present invention may be connected to the meteorological office server 30, KEPCO server 32 and the management server 34 through the Internet network.

The Meteorological Agency server 30 provides information including an expected weather, and the expected weather means information including an hourly and daily expected temperature and humidity.

KEPCO server 32 provides information including the power supply and demand alarm status. The power supply alarm status can be divided into stages according to the amount of reserve power. For example, if the reserve power exceeds 4 million KW, it is stable. Attention level of 10,000 KW can be divided into critical if the reserve power is 1 million KW to 2 million KW level, and serious if the reserve power is less than 1 million KW. That is, the KEPCO server 32 may provide the information on the steps as described above in the power supply and demand alert state.

The management server 34 refers to a computer or server used by a building manager to manage a building, and includes information on weather forecasts provided by the Meteorological Agency server 30 or a power supply alert state provided by the KEPCO server 32. It can be configured to provide information in response to casting over the Internet.

An embodiment according to the present invention includes an energy management module 36, which is connected to a power sensor 18, a weather sensor 20, and an indoor sensor 22, and is connected to a meteorological office server through an internet network. 20, the KEPCO server 32 and the management server 34 can be connected.

The energy management module 36 is connected for control with each facility (air conditioner 10, air conditioner 12, lighting device 14, etc.) while receiving monitoring information from each facility.

By the above configuration, the energy management module 36 provides temperature and humidity set points to the facilities by comparing the outdoor weather conditions with the indoor conditions, and analyzes the power usage to supply power to the equipment when the preset proper power usage is exceeded. It performs a peak operation to control the supply of, and is connected to an external server through the Internet, and has the function of setting the appropriate power usage by applying at least one or more of the expected weather and power supply alert conditions.

More specifically, the energy management module 36 includes an Ethernet model 40, a memory 42, a monitoring unit 44, a control panel 46, an analysis unit 48, and a control module 50.

The Ethernet modem 50 connects to an external server including a meteorological office server 30, a KEPCO server 32, and a management server 34 via the Internet.

The memory 42 includes an outdoor weather condition including the outdoor temperature and humidity sensed by the weather sensor 20, an indoor weather condition including the temperature and humidity of the room sensed by the indoor sensor 22, and an analyzer 48. Set the temperature and humidity set point, the appropriate power consumption analyzed by the analysis unit 48, and stores the predicted weather and power supply alert state cast through the Internet.

The monitoring unit 44 collects information on the operation state of the facilities including the air conditioner 10, the air conditioner 12, and the lighting device 14, and provides the collected information to the control module 50.

The control panel 46 transmits the temperature and humidity set point transmitted from the control module 50 to the facilities and controls the operation of the facilities corresponding to the peak power.

The analysis unit 48 compares the outdoor weather state and the indoor state through the control module 50, provides the temperature and humidity set points to the facilities through the control panel 46, and uses the power consumption sensed by the power sensor 18. In the case of exceeding the preset appropriate power consumption by using the analysis to provide the analysis module for the peak operation referring to the operating state of the facilities provided by the monitoring unit 44 to the control module 50, the expected weather stored in the memory 42 Appropriate power usage is set by applying at least one or more of the power supply and demand alarm conditions.

Here, the appropriate power consumption may be calculated based on the contract power, and may be determined by calculating the contract power to be reduced at a constant rate based on the predicted weather and power supply and demand alarm conditions.

In addition, the control module 50 receives the sensing signals of the weather sensor 20, the indoor sensor 22, and the power sensor 18, stores them as historical data in the memory 42, and provides them to the analyzer 48. The temperature and humidity set point provided by the analyzer 48 is transmitted to the control panel 46, and a control signal for controlling peak operation is provided to the control panel 46 based on the analysis information of the analyzer 48.

The energy management module 36 manages a set point for the amount of CO ₂ for controlling the circulation of indoor air in the memory 42 or the analyzer 48, and presets the amount of CO ₂ sensed by the indoor sensor 22. When the set point is exceeded, a damper (not shown) of the air conditioner 10 is controlled to control circulation of indoor air.

In addition, the control module 50 of the energy management module 36 may perform at least one or more of peak operation stepwise power output adjustment and operation control of the facility according to a predetermined schedule.

That is, the control module 50 first lowers the voltage of the power output from the power supply device 16 to the facilities when the power usage exceeds the proper power amount by the analysis information of the analysis unit 48, thereby reducing the overall power usage. Peak operation can be controlled to reduce.

And, if the power usage exceeds the appropriate amount of power by the analysis information of the analysis unit 48, the control module 50 by dividing the facilities by type and by the location of the room in accordance with the schedule to limit the supply of power in step by step Peak operation can be controlled to reduce usage.

Meanwhile, the analyzer 48 may set an appropriate power consumption by referring to the outdoor weather state, the indoor state, the temperature and humidity set point, and the power usage, which are managed as historical data in the memory 42.

In the smart energy management system according to the present invention configured as described above, sequential control may be performed by the method of FIGS. 2 and 3.

First, the control module 50 scans the weather sensor 20 and the indoor sensor 22 (S10), and the analysis unit 48 calculates a temperature and humidity set point by comparing indoor and outdoor temperature and humidity, and then installs the equipment through the control panel 46. It may be provided as (S12). The temperature and humidity set point may be provided to an individual facility having a function of adjusting the temperature and humidity, such as the air conditioner 10 and the air conditioner 12, and may be referred to the peak control.

When the control module 50 senses that the amount of CO ₂ exceeds the set point by the indoor sensor 22 (S14), the control module 50 controls the damper of the air conditioner 10 (S16) to perform indoor ventilation. have.

In addition, the control module 50 scans the power sensor 18 to receive power usage, and the above-described indoor / outdoor temperature / humidity, temperature-humidity set point, and power usage may be updated with history data in the memory 42 (S20).

Then, the control module 50 scans the Internet casting data through the Ethernet modem 40 (S22). The control module 50 is the expected weather and KEPCO server of the meteorological office server 30 which is the casting data through the Internet. The power supply and demand alarm state of 32 is scanned (S22) and stored (S24).

The control module 50 controls the analysis unit 48 to calculate an appropriate power consumption calculated by applying at least one or more of an expected weather condition and a power supply and demand alarm state (S26), and based on the calculated appropriate power usage. Analyze That is, the control module 50 compares the power peak with the contract power based on the appropriate power usage (S30) and controls the peak operation for controlling the supply of power supplied to the facility according to the analyzed result (S32).

In the process of controlling the peak operation, the analyzer 48 may analyze the predicted power consumption according to the peak operation, and the control module 50 may provide the predicted power consumption to the management server 34 through the Internet.

As described above, the analyzer 48 may apply at least one or more of the expected weather and the power supply and demand alert state, and calculate the predicted power usage by referring to the historical data, which may be selectively performed by the manufacturer.

In addition, in the peak operation, the analysis unit 48 receives the monitoring information of the monitoring unit 44 by the control module 50 (S40), and the control module 50 supplies power according to the analysis result of the analysis unit 48. When the amount of use exceeds the appropriate amount of power (S42), the power supply device 16 may be controlled to adjust the output of power supplied to the facilities in stages (S44). At this time, adjusting the power output means depressurizing the voltage in stages.

In addition, the control module 50 may perform the operation control of the facility according to the schedule when the power usage exceeds the appropriate power usage (S46).

At this time, the schedule can control the operation of the equipment to restrict the supply of power in stages by classifying the equipments to which power is supplied as a result of monitoring and by the location of the room.

That is, the limitation of the power supply by the schedule can be managed by assigning a power supply priority to each facility and each location of the facility. For example, the air conditioner 10 may be given priority to the air conditioner 12 to stop operation, and the operation may be stopped by a preset floor or a position among the plurality of air conditioners 12 or the lighting device 14. .

As described above, according to the smart energy management system according to the present invention, the embodiment may automatically adjust the temperature and humidity of the room and ventilate according to external weather conditions.

In addition, an embodiment according to the present invention may perform peak operation in which power usage is limited based on an appropriate power usage calculated by referring to an expected weather or power supply and demand warning state transmitted as casting data through the Internet.

In addition, by the peak operation, the power consumption is limited step by step according to the expected weather conditions or the power supply and demand situation, thereby saving energy.

10: air conditioner 12: air conditioner
14 lighting device 16 power supply
18: power sensor 20: weather sensor
22: indoor sensor 30: Meteorological Agency server
32: KEPCO server 34: management server
36: energy management module 40: Ethernet modem
42: memory 44: monitoring unit
46: control panel 48: analysis unit
50: control module

Claims (10)

Facilities driven by electric power;
A power supply for supplying the power to the facilities;
A power sensor for sensing power usage of the power supply device;
A weather sensor for sensing an outdoor weather condition including temperature and humidity;
An indoor sensor sensing an amount of CO ₂ and an indoor state including the temperature and humidity;
An external server including at least one of a meteorological office server for providing an expected weather and a KEPCO server providing a power supply and demand alert state; And
A peak for controlling the supply of power supplied to the facility when the outdoor weather state and the indoor state is provided to provide a temperature and humidity set point to the facilities, and analyzing the power usage to exceed a preset suitable power usage. And an energy management module configured to perform an operation and to be connected to the external server through the Internet, and to set the appropriate power consumption by applying at least one of the expected weather and the power supply and demand alarm state.
The energy management module,
An Ethernet modem for connecting to the external server through the Internet;
A memory for storing the outdoor weather condition, the indoor weather condition, the temperature and humidity set point, the appropriate power usage amount, the expected weather condition, and the power supply / demand alarm condition;
A monitoring unit for providing information on operating states of the facilities;
A control panel for transmitting the temperature and humidity set points to the facilities and controlling the operation of the facilities corresponding to the peak power;
Compare the outdoor weather conditions with the indoor conditions to provide temperature and humidity set points to the facilities, and analyze the power usage to analyze analysis information for the peak operation with reference to the operation state when the preset appropriate power usage is exceeded. An analysis unit configured to set the appropriate power consumption by applying at least one of the expected weather and the power supply and demand alarm state; And
Receive sensing signals of the meteorological sensor, the indoor sensor, and the power sensor and provide them to the analysis unit, transfer the temperature and humidity set point provided from the analysis unit to the control panel, and perform the peak operation based on the analysis information of the analysis unit. Smart energy management system comprising a; control module for providing a control signal for control to the control panel.
The method according to claim 1,
The energy management module is a smart energy management system for controlling the circulation of indoor air by controlling the damper of the air conditioner included in the facilities when the amount of CO ₂ exceeds a preset set point.
The method according to claim 1,
The energy management module includes at least one or more of stepwise power output adjustment and operation control of the facility according to a predetermined schedule in the peak operation.
The method of claim 3,
The schedule comprises the step of limiting the supply of power by classifying the facilities by type and location of the room.
The method according to claim 1,
The energy management module manages the outdoor weather state, the indoor state, the temperature and humidity set point, and the power consumption as historical data,
Smart energy management system for setting the appropriate power usage by further applying the history data.
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