KR101497984B1 - Real-time power measurement apparatus, power management server and method therefor - Google Patents

Abstract

A real time power measurement device is provided. The real-time power measurement apparatus includes a measurement value collection unit for collecting a single-phase current and a single-phase voltage measured at predetermined time intervals from a meter current transformer (CT), and a single- Phase power integrated value; and a three-phase power integrated value calculation unit for calculating a three-phase power integrated value based on the single-phase power integrated value, Phase power data corresponding to the number of single-phase power pulse signals from when one of the integration pulses is generated until the other one of the integration pulses is generated, And a transmission unit for transmitting the integrated pulse and the single phase power data to the power management server.

Description

REAL-TIME POWER MEASUREMENT APPARATUS, POWER MANAGEMENT SERVER AND METHOD THEREFOR,

The present invention relates to a power management system capable of measuring the amount of power energy used in an electric facility facility in real time, displaying measured data on the web, and managing and controlling an electric facility facility in real time.

Conventional technology is a method of cumulatively accumulating 1 kw with respect to electric power consumption. It is impossible to collect data on electric power consumption before reaching 1 kW, so that it is impossible to measure electricity consumption in real time, and accordingly, And it is difficult to efficiently manage electric devices. Further, there is a problem in that there is no power management system that can recognize the excessive use of power consumption and peak power in advance and can automatically or manually control the problematic electrical equipment.

In terms of measuring the electric power consumption of electric power facilities and electric appliances at large workplaces and efficiently managing power usage peak value and electric power consumption, which are the main indicators of the electricity charging standard, the existing electric power management systems Therefore, there is no software for calculating and analyzing the power consumption even though the power consumption can be accurately measured. Therefore, it is not possible to perform real-time control of the electric equipment according to the power consumption and the peak power, In terms of practicality, efficiency, and convenience.

On the other hand, as a prior art, Korean Patent Application Publication No. 10-2006-0035189 discloses an invention entitled " Electronic Power Measurement Apparatus Having a Cumulative Energy Estimation Function by Time Period " The present invention relates to a technology for determining whether power measurement is performed in accordance with a use time zone by verifying the metering of the amount of power and determining whether the accumulated power amount is accumulated correctly.

However, the prior art described above has a problem in that it can not monitor and measure the power consumption in real time.

Accordingly, there is a growing need for a real-time power management system capable of solving these problems, accurately measuring electricity usage, meaningful analysis and control of measured values, and unifying them in a power management server.

It is an object of the present invention to provide a real-time power management system capable of real-time measurement of electric power consumption in an electric facility facility and efficient management of overuse electric equipment and electric equipment. .

It is another object of the present invention to provide a virtual appliance which can conveniently manage individual buildings, floors, and electric devices of a large workplace by grouping them into virtual devices and setting a threshold value for each virtual device, And to provide a real-time power management system capable of performing automatic control on an electric device.

It is still another object of the present invention to provide a real-time power management system capable of interfacing with a central power management server by using a wireless LAN and separately managing and controlling the power measurement apparatus installed in an electric facility, .

According to a first aspect of the present invention, there is provided a real-time power measuring apparatus including a measurement value collecting unit for collecting a single-phase current and a single-phase voltage measured at predetermined time intervals from a current transformer CT, A single phase accumulation unit for calculating a single phase power value at the predetermined time intervals using the collected single phase current and single phase voltage and accumulating the single phase power values to generate a single phase power accumulated value, A three-phase integration unit for generating a three-phase power integration value by the three-phase power integration value and generating one integration pulse each time the three-phase power integration value is integrated in a predetermined unit, Phase power generation unit for generating the single-phase power data by the number of the pulse signals included in the single-phase power integration value until the integration pulse of the And a transmitting unit for transmitting the single-phase power data to the power management server.

The power management server interlocked with the real time power measurement device according to the second aspect of the present invention may further include a data reception unit for receiving the single phase voltage, the integration pulse and the single phase power data from the real time power measurement device, Phase voltage and single-phase power data, and a data processing unit for processing the single-phase voltage, the single-phase power data, and the current amount by a predetermined time unit to calculate periodic data And a graph generating unit for graphically displaying the generated data for each period.

The real-time power management method using the power management server according to the third aspect of the present invention includes the steps of receiving measurement value data from a real-time power measurement device, generating current amount data based on the measurement value data, Value data and the current amount data by a predetermined time unit to generate period-by-period data, and generating a graph using the generated period-by-period data.

According to the above-mentioned problem solving means of the present invention, the power measuring apparatus installed in the electric equipment to be managed communicates with the central power management server by using the LAN module without having an individual processing unit, It is possible to transfer the measurement data to the server and to receive and execute the control command for the individual electric equipment from the power management server, thereby enabling efficient power management.

In addition, according to the above-mentioned object of the present invention, it is possible to measure the power consumption of the electric equipment to be managed in real time, set a threshold value for each electric equipment, It is possible to automatically and automatically control the power supply to the corresponding electrical equipment so that convenient and efficient power management is possible.

1 is an overall schematic diagram of a real-time power management system, in accordance with an embodiment of the present invention.
2 is a detailed configuration diagram of a real-time power measurement apparatus according to an embodiment of the present invention.
3 is a detailed configuration diagram of a power management server according to an embodiment of the present invention.
4 is a detailed flowchart of a real-time power management process according to an embodiment of the present invention.
5 is a diagram illustrating a process of setting virtual device data in the power management server according to an embodiment of the present invention.
6 is a diagram for explaining a process of processing periodical data data in the power management server according to an embodiment of the present invention.
7 is a diagram for explaining a threshold monitoring and automatic control process in the power management server according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when a part is referred to as being "connected" to another part, it includes not only "directly connected" but also "electrically connected" with another part in between . Also, when an element is referred to as "comprising ", it means that it can include other elements as well, without departing from the other elements unless specifically stated otherwise.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is an overall schematic diagram of a real-time power management system, in accordance with an embodiment of the present invention.

As shown in FIG. 1, the real-time power management system 10 can integrally manage one or more buildings, and includes a real-time power measurement device 100 and a power management server 200. The mobile terminal 300 may further include a user mobile terminal 300 interlocked with the power management server 200.

Specifically, the real-time power management system 10 can be configured to manage one or more buildings (buildings 1 to n), and can set management targets by building, floor, or electrical equipment.

A real-time power measurement apparatus 100 is installed in the water distribution facility 510 of the building, the data relay facility 520 of each floor and the individual electric apparatus 530 to measure the electricity usage amount, To the power management server 200 of FIG.

For example, the real-time power management system 10 manages individual buildings 1 to n as objects to be managed and measures voltage, current, and power from the water distribution facility 510 installed for each building, And can transmit the measured values to the management server 200. In addition, buildings may be divided into layers, and a data relay facility 520 may be provided for each layer, and voltage, current, and power consumption may be measured for each layer and transmitted to the power management server 200. It is also possible to measure the amount of usage for each individual electric device 530 and perform individual control.

In the present specification, the water distribution facility 510, the data relay facility 520, and the individual electric devices 530 will be referred to collectively as the electric equipment 500.

The measurement data collected from the real-time power measuring apparatus 100 installed in the electric equipment 500 is transmitted to the power management server 200. The power management server 200 collects and processes the measurement data, And cumulative information can be provided to the user through a screen such as a graph. In addition, the processed information may be transmitted to and displayed on the user mobile terminal 300 interlocked with the power management server 200.

Next, the detailed configuration of the real-time power measuring apparatus will be described.

2 is a detailed configuration diagram of a real-time power measurement apparatus according to an embodiment of the present invention.

2, the real-time power management apparatus 100 includes a measurement value collection unit 110, a single-phase integration unit 120, a three-phase integration unit 130, and a single-phase data generation unit 140. Further, it may further include a transmission unit 150 and an electric device control unit 160.

The real-time power measuring apparatus 100 is installed individually in the electric equipment 500 and measures data such as electric power consumption and peak electric power of the electric equipment 500 in real time and transmits them to the power management server 200. The real-time power measurement apparatus 100 communicates with the power management server 200 through the LAN module and receives the control command from the power management server 200 to control the electrical equipment apparatus 500 to perform efficient power management .

The real-time power measuring apparatus 100 measures a maximum power of 10,000,000 single-phase power data during the period from the moment when the 1 kW accumulation pulse is transmitted to the time when the next pulse is transmitted, while the conventional power measuring apparatus measures the power consumption by sending the accumulation pulse in units of 1 kW And further to the power management server 200, it is possible to manage the power consumption of the electric device in real time.

The measurement value collecting unit 110 may collect single-phase currents and single-phase voltages periodically measured at predetermined time intervals in a current transformer (CT). For example, the measurement value collecting unit 110 can measure the currents and voltages of the single-phase R, S, and T through the instrumental current transformer at a cycle of 1 second and transmit the measured currents to the single-phase integrating unit 120.

The measurement value collecting unit 110 may periodically or irregularly measure environmental information such as temperature and humidity of the surrounding environment in addition to periodically measuring the voltage, current, and the like. The measured environment information may be transmitted to the power management server 200 through a transmission unit 150 to be described later and provided to the user.

The single-phase integrating unit 120 receives the real-time measurement data and calculates the integrated value of the single-phase power. Specifically, the single-phase integrating unit 120 may calculate a single-phase power value at predetermined time intervals using the collected single-phase current and single-phase voltage, and accumulate the calculated single-phase power values to generate a single-phase power integrated value.

The three-phase integration unit 130 receives the accumulated single-phase power integration value from the single-phase integration unit 120, and calculates a three-phase power integration value based on the received single-phase power integration value. Also, the three-phase integration unit 130 generates one integration pulse every time the three-phase power integration value is accumulated in a predetermined unit. The accumulated pulse is transmitted to the power management server 200 through the transmission unit 150 and is used as data for determining the power consumption of the electric device in the power management server 200. Details will be described later in detail with reference to FIG.

The single phase data generating unit 140 generates single phase power data by the number of the power pulse signals included in the single phase power accumulated value for a period from the moment the three phase accumulator 130 sends the accumulation pulses to the time when the next accumulation pulse is transmitted, Lt; / RTI >

Since the number of single-phase power data generated by the single-phase data generation unit 140 differs according to the power pulse signal of the three-phase integration unit 130, It is possible to calculate the number of single-phase power data corresponding to the integrated power amount of 1 kW and set it in the power management server 200 in advance. For reference, in the case of 1 kW, it corresponds to about 900,000 single-phase power pulses in general. Therefore, by measuring the number of single-phase power pulses received after receiving the 1 kw cumulative pulse, the power consumption can be grasped more accurately than 1 kw in real time.

The transmission unit 150 transmits the measurement values collected in the real-time power measurement window 100 to the power management server 200. The measured values transmitted to the power management server 200 may include an accumulated pulse, single-phase power data, and a single-phase voltage collected from the CT.

The transmission unit 150 may use a TCP / IP protocol or a UDP protocol to transmit data to the power management server 200, and may use a LAN module included in the real-time power processing device 100.

The electric device control unit 160 receives a control command for the electric equipment 500 from the power management server 200 and controls the electric equipment 500 according to the received control command. For example, when the electric device control unit 160 receives the control command, the electric device control unit 160 can stop operation of the electric equipment device 500 by shorting the line connected to the power switch of the electric equipment device 500 via the relay. The automatic control will be described in detail later with reference to FIG.

In addition, the real-time power measurement apparatus 100 may include an unillustrated LAN module for accessing the Internet and communicating with the power management server.

Next, the detailed configuration of the power management server will be described.

3 is a detailed configuration diagram of a power management server according to an embodiment of the present invention.

3, the power management server 200 includes a data receiving unit 210, a scaling unit 220, a data processing unit 230, a virtual device management unit 240, a periodic data processing unit 250, A graph generating unit 260 and a threshold value exceeding control unit 270. [

The power management server 200 collects measurement data received from the real-time power measurement apparatus 100, processes it on a cycle-by-cycle basis, and displays it on the screen in real time. The plurality of electric equipment 500, Can be grouped into an arbitrary virtual device and managed. In addition, it is possible to configure a threshold value for power consumption and peak power for each virtual device, and automatically control the electric equipment when the threshold value is exceeded.

The data receiving unit 210 receives measurement data from the real-time power measuring apparatus 100 installed in the electric equipment 500. Specifically, the data receiving unit 210 may receive the single phase voltage, the accumulation pulse, and the single phase power amount data generated at an arbitrary time interval from the real time power measurement device 100.

The scaling unit 220 converts the measured value data transmitted from the real-time power measuring apparatus according to the magnification of the CT. Specifically, the CT can not directly measure the large current of the primary side. Therefore, the transformed value of the current is reduced at a certain rate, and the scaling unit 220 scans the transformed value received from the real-time power measurement apparatus 100 The measured value data can be reconverted.

For reference, the magnification depends on CT, and there are types such as 5/1000, 5/800, 5/400, and the current measurement range is 0 to 5 [A]. Therefore, the data converted to the original primary large current value can be obtained by multiplying the measured value data by the magnification (200, 160, 80).

The data processing unit 230 calculates the amount of power consumption based on the integrated pulse and the single-phase power data in real time, and calculates the amount of current based on the single-phase voltage and the single-phase power data.

Specifically, the data processing unit 230 can calculate the current power consumption at the present time based on the integrated pulse and the single-phase power data transmitted from the real-time power measurement apparatus 100. [ If the accumulated pulse is transmitted in units of 1 kW, the accumulated power pulses received can be used up to a unit of 1 kW. When the sum of the received single-phase power data after receiving the last accumulated pulse is multiplied by the amount of power corresponding to one single-phase power data, the power consumption in units smaller than 1 kW can be obtained. The sum of the two is the power consumption at the present time.

For example, when the cumulative pulse is set to be transmitted in units of 1 kW, and the measurement result shows that 1 kw corresponds to 900,000 single-phase power data, 20 cumulative pulses are received, and after the last received cumulative pulse When receiving 500,000 single-phase power data, the cumulative power consumption at that point is 20 * 1kw + (50/90) * 1kw = 20.56kw.

The serial number of the single-phase power data is incremented from 1 in ascending order, and is counted again at 1 when the transmission of the 1 kw cumulative pulse ends and accumulation of the new 1 kw cumulative amount starts again.

On the other hand, the data processing unit 230 can calculate the single-phase current value. The data processor 230 may calculate the single-phase current value by substituting the single-phase voltage and the single-phase power into the calculation formula in order to graphically represent the voltage and the current consumption in real time. The single-phase current value can be obtained by applying the equation of "current value = total power / (voltage * 1.732)", and conversely, The amount of current can be calculated.

The virtual device management unit 240 groups and manages the building and electric equipment as a power management object into one or more virtual devices. Specifically, the virtual device management unit 240 groups individual building or electric facility devices, and the power usage and peak power of buildings or electric facility devices belonging to each group can be expressed numerically by being added to the virtual group.

A method of generating virtual device data will be described with reference to FIG. 5. A method of generating virtual device data is described with reference to FIG. 5, in which the building 1 (T511) to the building 6 (T516) included in the entire workplace T500 as a power management target is divided into three virtual machines T531 to T533 ), And measurement apparatus 1 (T521) to measurement apparatus 6 (T526) were grouped into four virtual apparatuses (T534 to T537). In this case, the virtual device 1 (T531) includes the building 1 (T511) and the building 2 (T512), and the power consumption and peak power of the virtual device 1 (T531) It is the sum of power usage and peak power. Similarly, the virtual device 4 (T534) includes the measuring device 1 (T521) and the measuring device 2 (T522), and the power consumption and the peak power of the virtual device 4 (T534) T522) and the peak power.

The settings of the virtual device can be freely created and changed by the workplace administrator.

The periodic data processing unit 250 processes the single-phase voltage, the single-phase power data, and the current amount for each unit of time specified in the server to generate data for each cycle. Referring to FIG. 6, a method of processing data for each period will be described. First, in the case where the measurement data is collected in units of 1 second in the CT, the data processing unit 250 for each cycle collects data (P611 (P621 to P625) are combined to generate one-minute data (P621), and five one-minute data (P621 to P625) are combined to generate five-minute data (P631). In this way, you can create 15-minute data, 1-hour data, and 1-day data. The time data of the data processing is 1 minute, 5 minutes, 15 minutes, 1 hour, 1 day. The data thus generated can be used as basic data for graph creation in the graph generating unit 260, And forecasting data.

The graph generating unit 260 displays the generated data for each period in a graph. The graphical parameters can be power, voltage, current, average power, peak power, past power, and so on.

The graph generated by the graph generating unit 260 may be transmitted to a device such as a smart mobile phone or the like, which is connected to the power management server 200, and may be displayed.

The over-threshold control unit 270 sets a threshold value for the power consumption and the peak power for the grouped virtual apparatus, and monitors whether or not the set threshold value is exceeded. Specifically, the threshold value exceeding controller 270 may set threshold values of three grades of Ninor, Major, and Critical for each virtual device, and may use an initial value automatically set by the system. The over-threshold control unit 270 performs monitoring according to the set threshold value, and performs automatic control according to the control algorithm when an over-threshold state occurs.

Referring to FIG. 7, the threshold setting, monitoring, and automatic control will be described in detail. The virtual device management unit 240 receives virtual device data (S710) and sets a threshold value for each virtual device (S720). The settable items may be, for example, threshold setting (S722) of power consumption or threshold setting (S724) of peak power. Thereafter, the processed data is periodically received from the periodic data processing unit 250 in step S730, and the threshold value for the virtual device is monitored based on the received data in step S740.

The alarm generation is performed by setting an alarm generation reference value for each virtual device (S750). For example, if the alarm generation threshold value for the power consumption is selected as Major, if the power consumption amount of the virtual device exceeds Minor, the alarm generation threshold value can be selected as an alarm The alarm will be generated only when it exceeds the major.

Also, the execution of the control algorithm is also performed according to the set automatic control reference value (S760). For example, when the peak power of the virtual device exceeds the critical value, the automatic control is not performed. If the peak power of the virtual device exceeds the critical value, the braking control is executed.

When the automatic control is executed, the over-threshold control unit 270 sends a control command to the real-time power control apparatus 100 (S770), and the real-time power measurement apparatus 100 transmits the control command to the electrical equipment 500 (Step S780). Through such threshold monitoring and automatic control, management of power usage and peak power at the workplace can be performed automatically.

Next, a real-time power management method using the power management server will be described.

4 is a detailed flowchart of a real-time power management process according to an embodiment of the present invention.

As shown in FIG. 4, first, the power management server 200 receives measurement value data from the real-time power measurement apparatus 100 (S400). The measured value data may be collected from the CT and may include, for example, single phase voltage, cumulative pulse and single phase power data.

Thereafter, the received measured value data is multiplied by the magnification of CT (S410), and the converted measured value data is processed to calculate single-phase current amount data (S420). Then, the building and electrical equipment to be subjected to power management are grouped into one or more virtual devices (S430), and the calculated current amount data and measured value data are processed for an arbitrary time unit to generate data for each cycle (S440) .

Then, a graph is generated in real time using the generated data for each period and displayed on the screen (S450). It is also possible to set thresholds for power usage and peak power for the grouped virtual devices and monitor for exceeding the thresholds, and if the power usage or peak power of the virtual device exceeds the threshold, Control is executed (S460).

One embodiment of the present invention may also be embodied in the form of a recording medium including instructions executable by a computer, such as program modules, being executed by a computer. Computer readable media can be any available media that can be accessed by a computer and includes both volatile and nonvolatile media, removable and non-removable media. In addition, the computer-readable medium may include both computer storage media and communication media. Computer storage media includes both volatile and nonvolatile, removable and non-removable media implemented in any method or technology for storage of information such as computer readable instructions, data structures, program modules or other data. Communication media typically includes any information delivery media, including computer readable instructions, data structures, program modules, or other data in a modulated data signal such as a carrier wave, or other transport mechanism.

It will be understood by those skilled in the art that the foregoing description of the present invention is for illustrative purposes only and that those of ordinary skill in the art can readily understand that various changes and modifications may be made without departing from the spirit or essential characteristics of the present invention. will be. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

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.

Claims (13)

A real-time power measuring apparatus comprising:
A measurement value collecting unit for collecting single-phase current and single-phase voltage measured at predetermined time intervals from a meter current transformer (CT)
Calculating a single-phase power value at the predetermined time intervals using the collected single-phase currents and single-phase voltages, and accumulating the single-phase power values to generate a single-phase power sum value;
A three-phase integration unit for calculating a three-phase power integration value based on the single-phase power integration value and generating one integration pulse each time the three-phase power integration value is integrated in a predetermined unit,
A single-phase data generator for generating single-phase power data by the number of single-phase power pulse signals from when one of the accumulation pulses is generated to before another consecutive accumulation pulse is generated, and
And a transmission unit for transmitting the integrated pulse and the single-phase power data to the power management server
And a real-time power measurement device.
The method according to claim 1,
Further comprising a control unit for receiving a control command for the electric equipment from the power management server, and for controlling the electric equipment in response to the control command.
The method according to claim 1,
Further comprising a LAN module for accessing the Internet and communicating with the power management server,
Wherein the transmitting unit transmits the accumulated pulse and single-phase power data to the power management server using the LAN module.
A power management server interlocked with a real time power measurement device,
A data receiving unit for receiving the single-phase voltage, the cumulative pulse and the single-phase power data from the real-
A data processing unit for calculating the amount of power consumption based on the integrated pulse and the single-phase power data in real time, and calculating the amount of current based on the single-phase voltage and the single-phase power data,
A periodic data processing unit for periodically processing the single-phase voltage, the single-phase power data, and the amount of current by a predetermined time unit,
A graph generating unit for graphically displaying the generated data for each period;
Phase power data received from the real-time power measurement device according to a predetermined magnification,
And a power management server.
delete 5. The method of claim 4,
Further comprising: a virtual device management unit for grouping and managing the building and electrical equipment as power management targets into one or more virtual devices.
The method according to claim 6,
Further comprising a threshold exceeding controller for setting a threshold value for power consumption and peak power for the grouped virtual device and for monitoring whether the threshold value is exceeded.
8. The method of claim 7,
Wherein the threshold exceeding control unit sends a control command to the real-time power measuring device to cause the electrical equipment corresponding to the virtual equipment to shut down when a threshold exceeding condition occurs in the virtual device. .
8. The method of claim 7,
Wherein the threshold value is set to three levels of Minor, Major, and Critical for each virtual device.
5. The method of claim 4,
Wherein the power management server is connected to the real time power measurement device using the Internet and can remotely monitor and control the electric equipment installed with the real time power measurement device.
A real-time power management method using a power management server,
Receiving measurement data from a real-time power measurement device,
Generating current amount data based on the measured value data,
Generating periodic data by processing the measured value data and the current amount data every predetermined time unit,
Generating a graph using the generated periodic data; and
Converting the measured value data received from the real-time power measuring device according to a predetermined scale factor
/ RTI >
12. The method of claim 11,
Further comprising the step of grouping the building and electrical equipment to be power managed into one or more virtual devices.
13. The method of claim 12,
Setting a threshold for power usage and peak power for the grouped virtual device and monitoring for exceeding a set threshold.

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