KR20120036567A - Prediction for power demand based on web, observation system for power and energy, and method for the same - Google Patents

Abstract

PURPOSE: A web based electric power demand forecast, an electric power and energy monitoring system, and a method thereof are provided to display an electric power based service on a web screen, thereby saving for energy by monitoring the energy and electric power of buildings and households. CONSTITUTION: An electric power analyzing unit(110) analyzes the information for voltage and the total power consumption. An energy analyzing unit(120) analyzes information on electricity, gas, water supply, hot water, and heating. A power quality analyzing unit(130) analyzes information on the decrease rate and increase rate of power consumption. A monitoring unit(200) displays the analyzed information, comprehensive monitoring, a report, comprehensive analysis, information forecast, and environment configuration.

Description

Prediction for Power Demand based on Web, Observation system for Power and Energy, and Method for the same}

The present invention relates to a power monitoring system, and more particularly, to a web-based power demand prediction, power and energy monitoring system and method for reducing power consumption.

In general, the power monitoring system is a power system such as a transmission and distribution system, or a power distribution system such as a factory equipped with various industrial equipments. It refers to a series of systematic systems that monitor and control the power in the event of a power accident.

In order to secure the reliability and stability of the system operation, such power monitoring system doubles various facilities and networks and operates interface modules to flexibly interoperate with other systems. Furthermore, additional functions such as data communication and remote monitoring control functions are also provided. I'm doing it.

In general, the electricity meter displays the amount of power used by the user by integrating and displaying an absolute value of the amount of power used by the user. However, the charge for the amount of power used is applied to the cumulative price, the more you use the more you will be charged. In addition, since charges increase in stages, charges increase rapidly when a certain amount is used.

There have been attempts to reduce the electricity bill by adjusting the amount of electricity used according to the electricity usage fee system.

An example of a technique for a power meter for managing the power used as described above is disclosed in [Korean Registered Utility Model 20-0322487 (published on July 29, 2003), "Power-managed power meter" (hereinafter, referred to as Prior Art 1).

The prior art 1 predicts monthly usage based on the accumulated power amount, and sets the amount of power to be used per day by referring to the predicted monthly power amount. By comparing the set daily power consumption with the actual measured daily power consumption, a configuration is provided to sound an alarm when the daily power usage exceeds the set daily power usage.

In addition, an example of another technique is disclosed in [Korean Registered Utility Model 20-0354156 (published Jun. 11, 2004), "Power Saving Indicator" (hereinafter, referred to as Prior Art 2).

The prior art 2 relates to a technology for warning a user when electric power is used for a predetermined time while displaying and converting an electric charge according to the usage into a progressive charge. In particular, the green LED to be turned on when the used amount is less than the first accumulated value, the yellow LED to be lit when the amount is less than the secondary accumulated value, and the red LED to be lit when the used amount is more than the third accumulated value, In addition, a configuration is disclosed to enable warning according to the accumulated value.

However, the prior arts have a problem in that goal setting is uniform, such as setting a daily use target amount by averaging monthly power usage. For example, the amount of power used by office workers at home can vary significantly between weekday and weekend use. Office workers spend most of their time at work on weekdays, so they will use less power at home. On the other hand, on weekends, the amount of time you spend at home will be high. Conversely, power consumption at work will be high during the week and less on weekends.

In addition, the prior art has a problem that it is not possible to monitor the amount of power used in real time. Prior art 1 monitors daily usage based on monthly usage, and prior art 2 does not specifically mention period. Prior art 2 shows the expected amount to be charged according to power usage, but is not monitored at the beginning of the month because it is based on the cumulative amount of power used.

That is, Prior Art 2 shows the cumulative power consumption or its estimated charge "in real time", but cannot be monitored.

In order to monitor the power consumption in real time, it is necessary to measure the power consumption every minute or every hour and monitor whether the power consumption exceeds the target power consumption. However, the prior arts cannot monitor the real-time power consumption substantially because the target power is an average value or a cumulative amount.

The present invention is to solve the conventional problems as described above, the web-based power demand prediction to save energy through the energy monitoring, power monitoring of buildings and consumers in real time by displaying the power-based service on the web screen, Its purpose is to provide a power and energy monitoring system and method.

Web-based power demand prediction, power and energy monitoring system according to the present invention for achieving the above object is the power analysis to analyze the information received by the user in total power consumption, voltage, power factor, reactive power, current, unbalance rate And an energy analysis unit that receives and analyzes information on electricity, gas, water, hot water, and heating of the user, and receives and analyzes information on a reduction rate and an increase rate of power use supplied to the user; Characterized in that it comprises a monitoring unit for displaying information, comprehensive monitoring, reports, comprehensive analysis, information prediction, environmental settings analyzed by the power analysis unit, energy analysis unit and power quality analysis unit.

In addition, the web-based power demand prediction, power and energy monitoring method according to the present invention for achieving the above object comprises the steps of receiving the analyzed information on the power, energy, power quality used in real time from the customer; Comparing the information about the delivered power, energy, and power quality with a reference value; Storing related data when the analyzed information value is less than or equal to a reference value, and creating and expressing a related report on power and energy related information based on the stored data; Calculating a location where power and energy are consumed by applying a least square method when the analyzed information value is greater than or equal to a reference value; Predicting and expressing a location and information of high power consumption or energy usage to a user or an administrator based on the calculated information; And storing the predicted data and expressing the stored predicted data.

Web-based power demand prediction, power and energy monitoring system and method according to the present invention has the following effects.

In other words, power-based services can be displayed on a web screen to save energy through energy monitoring and power monitoring of buildings and consumers.

1 is a schematic view showing a web-based power demand prediction, power and energy monitoring system according to the present invention
2 to 5 are information screens for the main screen, power analysis, energy analysis and power quality analysis respectively displayed on the monitoring unit of FIG.
6 is a flow chart schematically showing a web-based power demand prediction, power and energy monitoring method according to the present invention

Hereinafter, a web-based power demand prediction, power and energy monitoring system and method according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic diagram showing a web-based power demand prediction, power and energy monitoring system according to the present invention.

Web-based power demand prediction, power and energy monitoring system according to the present invention, as shown in Figure 1, power analysis to analyze the information received by the user, the total power consumption, voltage, power factor, reactive power, current, unbalance rate The unit 110, the energy analysis unit 120 for receiving and analyzing the information of the electricity, gas, water, hot water, heating of the user, and the power use reduction rate (sag) and increase rate (swell) supplied to the user Receive and analyze the information about the power quality analysis unit 130, the power analysis unit 110, the energy analysis unit 120 and the power quality analysis unit 130, the information analyzed, comprehensive monitoring, reports, comprehensive analysis And a monitoring unit 200 for displaying information prediction and environment settings.

Here, if the user is assumed to be an apartment complex or school, the power analyzer 110, the energy analyzer 120, and the power quality analyzer 130 analyze each piece of information about the apartment complex or the school as a whole. In addition, the monitoring unit 200 displays the power, energy, and power quality of each floor, generation, and elevator.

The monitoring unit 200 has a digital value or the amount of usage based on a reference value so that an administrator can easily understand the results analyzed by the power analyzer 110, energy analyzer 120, and power quality analyzer 130. It will be displayed in graph form.

The monitoring unit 200 is a comprehensive management system for performing a comprehensive diagnosis, according to the administrator's setting, by clicking on the building (apartment, factory, etc.), comprehensive monitoring, report, information analysis, information prediction, and environment setting. By checking the power, energy and power quality, it is possible to predict the power and energy usage in advance.

The most common problem due to instantaneous voltage fluctuations (capacity, voltage drop, voltage rise) supplied to the user is equipment failure. In many industries with significant loads, much time is required to restart the process, even if a process paralysis occurs due to momentary voltage fluctuations. As a result, as in the case of the result of the long duration variation (long duration variation) may cause problems in the industrial process, the instantaneous voltage fluctuation state is analyzed and displayed on the monitoring unit 200 through the power quality analyzer 130 in real time. do.

Here, the voltage drop (Sag) is a instantaneous sag, 30 cycles ~ 3 seconds when the effective value of the voltage occurs for about 0.5 ~ 30 cycles in the 0.1 ~ 0.9 pu (per unit, unit state) state of the rated voltage Momentaty Sag occurs when it lasts for 3 seconds to 1 minute is called Temporary Sag. Sag can be prevented by means of battery backup. Transformers, cables, Switchgear, CT & PT are not affected by Sag.

The voltage swell is instantaneous swell when the information of 0.5 ~ 30 cycles is generated with the effective value of the voltage 1.1 ~ 1.8pu of the rated voltage. When it lasts for about 1 minute, it is called Temporary Swell. In particular, frequency-sensitive equipment is severely affected by the swell. Seriously affected by the swell phenomenon are equipment that requires accurate speed devices, computers, and electronic control equipment.

The interruption is referred to as a momentaty interruption when the information occurs for 0.5 to 3 seconds when the effective value of the voltage is 0.1 pu or less, and is referred to as a temporary interruption when it lasts for about 3 seconds to 1 minute. Interruption can cause malfunctions in electronic control, computer control, and rotary machine control. It can reduce the inductance of motor contact and affect the equipment such as soft starter.

2 to 5 are information screens for a main screen, power analysis, energy analysis, and power quality analysis respectively displayed on the monitoring unit of FIG. 1.

As shown in FIG. 2, the screen of the monitoring unit 200 displays the entire power information, that is, the power, the voltage, the power factor, the reactive power, the current, and the unbalance rate that are analyzed by the power analyzer 110 in real time with respect to the customer building. The amount of gas, water, hot water and heating analyzed by the energy analyzer 120 is displayed as a digital value.

Therefore, the main screen displayed on the monitoring unit 200 can grasp power, energy, and power quality information of all the consumers in real time, and perform floor-based energy item monitoring, comparison monitoring according to the previous month and the current month.

In addition, the information on the current power consumption and energy consumption for each room in each floor can be confirmed in a list form, and the information on each floor according to the ON / OFF state of the elevator or light contacts can be confirmed.

On the other hand, the monitoring unit 200 is connected to a mobile terminal, a smart phone, a personal PC and wireless Internet, CDMA, wired and wireless communication, the administrator can monitor in real time in any outside space.

As shown in FIG. 3, the power usage of each floor of the user is displayed in real time on the screen of the monitoring unit 200. When the administrator selectively clicks a desired floor, the power usage of the corresponding floor is displayed.

Here, the search criteria item displayed on the screen of the monitoring unit 200 is configured to select a corresponding building, floor, and room, and may select a search criterion and a search period by selecting days, months, and years.

In addition, power, current, active power, reactive power, frequency, power factor, unbalance, and CO ₂ emissions can be displayed in real time.

As shown in FIG. 4, the energy information of each floor of the user is displayed in real time on the screen of the monitoring unit 200. When the administrator selectively clicks a desired floor, the energy usage information of the corresponding floor is displayed.

Here, the search criteria item displayed on the screen of the monitoring unit 200 is configured to select a corresponding building, floor, and room, and may select a search criterion and a search period by selecting days, months, and years.

As shown in FIG. 5, information about the power quality analyzed by the power quality analyzer 130 is displayed in real time on each floor of the user on the screen of the monitoring unit 200. Power quality information for the floor is displayed.

Here, the power quality reference point displayed on the screen of the monitoring unit 200 is generated according to the criteria of each item of the elevator, escalator, hallway light, etc., and Sag and Swell are applied to the power quality based on this criterion.

6 is a flow chart schematically showing a web-based power demand prediction, power and energy monitoring method according to the present invention.

In the web-based power demand prediction, power and energy monitoring method according to the present invention, as shown in Figure 6, the analyzed information on power, energy, power quality used in real time from the customer through a gateway such as the Internet Received (S101).

Subsequently, the information on the transferred power, energy, and power quality is compared with a reference value to determine it (S102).

That is, the power information on the total power consumption, voltage, power factor, reactive power, current and unsatisfaction rate of the consumer building is compared with preset reference values, and the energy information of electricity, gas, water, hot water and heating is preset. Compare with the reference value.

Subsequently, when the analyzed information value is less than or equal to the reference value, related data is stored (S103). Then, based on the stored data, a report related to power and energy related information is created and expressed (S104).

Subsequently, when the analyzed information value is greater than or equal to the reference value, the least square method is applied to calculate where a lot of power and energy are consumed (S105).

Here, the least square method calculates specific information from the analyzed power or energy by calculating a parameter of the titration model such that the sum of squares of errors from any statistical data is minimized.

Based on the calculated information, the user or manager specifically predicts that the power consumption or the energy usage is high in the number of rooms and the number of rooms (S106).

Subsequently, the predicted data is stored (S107), and the stored predicted data is represented (S108).

Therefore, the web-based power demand prediction, power and energy monitoring system and method according to the present invention monitors the main information on the total power consumption, voltage, power factor, reactive power, current and unsatisfactory rate of the consumer building, as well as electricity and gas. By monitoring the usage of water, hot water, and heating in a graphical form, all the basic information of the building can be viewed on the main screen.

In addition, it is possible to grasp the energy usage of each floor by displaying the energy usage of each floor for each floor of each building.

In addition, in the case of detailed monitoring of each floor, the actual drawing shows the location of each room and elevator escalator, lighting, etc. by matching the actual location with the actual figures. It is easy to use besides experts by enhancing the function, and it is easy to cope in case of an accident.

Since all MMI services are provided on the web, it can be monitored in any internet-enabled space to enhance IT functions, and it is easy to register the setting details of the equipment in the environment setting so that the building manager can easily set the equipment.

Based on the analyzed power and energy information, it calculates and monitors the power and energy usage used in each floor or each room including the total power usage and energy usage, and analyzes it through the minimum winner method. When used, energy savings can be realized by providing predictive information to users or administrators of where and what they are overusing.

On the other hand, it will be understood by those skilled in the art that various changes and modifications can be made without departing from the technical spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

110: power analysis unit 120: energy analysis unit
130: power quality analysis unit 200: monitoring unit

Claims (5)

A power analysis unit for receiving and analyzing information on the total power consumption, voltage, power factor, reactive power, current, and unbalance of the user;
An energy analysis unit for receiving and analyzing information about electricity, gas, water, hot water, and heating of the user;
A power quality analysis unit for receiving and analyzing information on a reduction rate and an increase rate of power supplied to the user;
Web-based power demand prediction, comprising a monitoring unit for displaying information, comprehensive monitoring, reports, comprehensive analysis, information prediction, environmental settings analyzed by the power analysis unit, energy analysis unit and power quality analysis unit , Power and energy monitoring systems. The method of claim 1,
The monitoring unit displays the amount of usage analyzed as a digital value or a graph based on a reference value so that the manager can easily identify the results analyzed by the power analysis unit, the energy analysis unit, and the power quality analysis unit. Demand forecasting, power and energy monitoring systems. The method of claim 1,
The monitoring unit is connected to a portable terminal, a smart phone, a personal PC through a wireless Internet, CDMA, wired and wireless communication, the web-based power demand prediction, power and energy, characterized in that the administrator is configured to monitor in real time in any outside space Surveillance system. The method of claim 1,
The monitoring unit grasps the power, energy and power quality information of all the consumers in real time through the displayed main screen, and executes the monitoring based on the energy items by floor, comparison monitoring according to the previous month and the current month. Forecasting, power and energy monitoring systems. Receiving analyzed information about power, energy, and power quality used in real time from a customer;
Comparing the information about the delivered power, energy, and power quality with a reference value;
Storing related data when the analyzed information value is less than or equal to a reference value, and creating and expressing a related report on power and energy related information based on the stored data;
Calculating a location where power and energy are consumed by applying a least square method when the analyzed information value is greater than or equal to a reference value;
Predicting and expressing a location and information of high power consumption or energy usage to a user or an administrator based on the calculated information;
And storing the predicted data, and expressing the stored predictive data.

Images