KR20120113538A - Digital power meter system and, method for error detecting thereof - Google Patents

Abstract

PURPOSE: A digital watt-hour meter system and a method for detecting the malfunction of a digital watt-hour meter are provided to determine the malfunction of the system by storing electricity values in three kinds of areas and comparing the electricity values with each other. CONSTITUTION: A main processor(100) and a sub processor(200) detect a voltage and a current of a distribution network(20). A data storage module(300) stores an electricity value measured in a previous time frame of the main processor as an electricity value of a current time frame. A control module(400) compares electricity values stored in current time fames of the main processor, the sub processor, and the data storage module with each other. The control module determines the malfunction of the main processor and the sub processor according to the comparison result. [Reference numerals] (110,210) Voltage detecting unit; (114) Main processing unit; (120,220) Current detecting unit; (130,230) A/D converter; (142,240) Signal calculating unit; (150) Main memory; (160) Display unit; (170) Communication device; (20) Distribution network; (250) Sub memory; (300) Data storage module; (400) Control module

Description

Fault detection method of digital electricity meter system and digital electricity meter

The present invention relates to a digital electricity meter system and a fault detection method of a digital electricity meter, and more particularly, to a fault detection method of a digital electricity meter system and a digital electricity meter capable of accurately measuring a power amount even when a fault is detected and a fault occurs in the electricity meter. .

Mechanical wattmeters have been widely used and used, but digital wattmeters have been increasingly used in recent years. For example, KEPCO plans to replace mechanical electricity meters with digital electricity meters by 2015, and is in the process of gradually replacing them.

The digital electricity meter converts an analog signal into a digital signal and measures the amount of power. For this purpose, a memory, a CPU, and the like are provided. In addition to the basic functions of power measurement, additional functions such as remote meter reading through communication function are added to enable the use of a high-performance, multi-function power meter. However, as functions increase and high-performance components are provided, the probability of occurrence of failure also increases.

In addition, smart grids and micro grids are being applied to each home and residential environment. In order to provide a real-time plan and improved power service in the smart grid environment, a digital electricity meter must be provided. In the smart grid environment, the digital electricity meter communicates in both directions to control the amount of electricity in the residential environment. If the digital electricity meter fails, service disruption may occur.

In order to solve this problem, it is to provide a digital electricity meter system and a failure detection method of the digital electricity meter that can more easily detect the failure of the digital electricity meter, and can measure the power amount stably even if the digital electricity meter fails.

The problem to be solved by the present invention is to provide a digital electricity meter system and a failure detection method of the digital electricity meter.

Digital meter system according to an embodiment of the present invention for achieving the above object, the main processor and sub-processor to measure the power for each time frame by detecting the voltage and current of the distribution network, in the previous time frame of the main processor Comparing the stored power values in the current time frame of the data storage module, the main processor, the subprocessor, and the data storage module to store the measured power values as power values of a current time frame. And a control module for determining whether there is a failure, and if there is a power value stored in a current time frame of the main processor, the subprocessor, and the data storage module, it is determined that there is no failure, and if the power values are not the same, the main processor or The subprocessor I think it's broken.

According to another aspect of the present invention, there is provided a method for detecting a failure of a digital electricity meter, the method comprising measuring power of a power distribution network for each time frame in a main processor and a subprocessor, and transferring the main processor from a data storage module. Storing a power value measured in a time frame as a stored value of a current time frame, comparing the stored power values in a current time frame of the main processor, the subprocessor, and the data storage module, and And determining whether there is a failure of the main processor, the sub-processor, and the data storage module when the stored power values are the same, and determining that there is no failure. The subprocessor We believe has failed.

According to another aspect of the present invention, there is provided a method for detecting a failure of a digital electricity meter, the method comprising: measuring power of a power distribution network in a main processor and a sub-processor at a first time, a main processor and a second time; Measuring a power of a distribution network in a sub-processor, and storing a power value measured at a first time of the main processor as a power value of a second time of a data storage module; at the second time, the main processor and the sub-processor And comparing the power values stored in the data storage module to determine whether the main processor and the sub processor have failed, and stored in the main processor, the sub processor, and the data storage module at the second time. If the power values are the same, it is determined that there is no failure. If the power values are not the same, the main It is determined that the processor or the subprocessor has failed.

According to the digital electricity meter system and the fault detection method of the digital electricity meter according to an embodiment of the present invention, the power value is stored in three areas and the three values are compared to determine whether the system is faulty. Therefore, it is possible to detect whether or not the digital electricity meter has failed in real time.

In addition, since a main processor and a sub-processor are provided so that when one of them fails, the other can perform power measurement, so that the system can operate without a gap of power measurement. On the other hand, in the digital electricity meter system and the failure detection method of the digital electricity meter according to an embodiment of the present invention, the subprocessor and data storage function are not simply three main processors but are simply configured with a configuration related to the measurement of the power amount in the main processor. By configuring a data storage module that performs only the three values, the three values can be compared and the failure can be determined, while the cost can be minimized and the configuration can be simplified.

1 is a block diagram schematically showing the configuration of a digital electricity meter system according to an embodiment of the present invention.
2 is a view for explaining a digital power meter system according to an embodiment of the present invention.
3 is a flowchart illustrating a failure detection method of a digital electricity meter according to an embodiment of the present invention.
4 is a block diagram schematically showing the configuration of a digital electricity meter system according to another embodiment of the present invention.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, it is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. It is intended that the disclosure of the present invention be limited only by the terms of the appended claims. Like reference numerals refer to like elements throughout.

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

1 is a block diagram schematically showing the configuration of a digital electricity meter system according to an embodiment of the present invention. 2 is a view for explaining a digital power meter system according to an embodiment of the present invention.

1 and 2, the digital electricity meter system 10 according to an embodiment of the present invention is connected to the distribution network 20 to measure power, and includes a main processor 100, a subprocessor 200, and data. Storage module 300 and control module 400.

The main processor 100 includes a voltage detector 110 connected to the power distribution network 20 to detect a voltage, and a current detector 120 connected to the power distribution network 20 to detect current, and the voltage detector 110. And an analog / digital converter 130 for converting the analog signal detected by the current detector 120 into a digital signal. In addition, the main processor 100 includes a CPU 140 for processing a signal received from the analog-to-digital converter 130 and controlling the overall configuration of the main processor 100, the CPU 140 receives the digital signal And a main processor 144 for processing and controlling operations of the main memory 150, the display unit 160, and the communication device 170. The main memory 150 stores the power value calculated by the signal calculator 142, the display 160 displays the power value calculated by the signal calculator so that the user can see it, and the communication device 170 displays the power. It enables bi-directional communication with the managing manager, real-time power measurement and remote control.

The subprocessor 200 includes a voltage detector 210 connected to the power distribution network 20 to detect a voltage and a current detector 220 connected to the power distribution network 20 to detect a current, and the voltage detector 210. And an analog / digital converter 230 for converting the analog signal detected by the current detector 220 into a digital signal, and the signal calculator 240 receiving the digital signal from the analog / digital converter 230 to calculate power. And a sub memory 250 that stores the power value calculated by the signal calculator 240.

The subprocessor 200 includes only a part of the main processor 100, and includes only a part of the main processor 100 that calculates and stores power. That is, the subprocessor 200 is configured with only a minimum number of components to perform the function of calculating and storing power instead of an error in the main processor 100.

On the other hand, the power supplied to the main processor 100 and the sub-processor 200 is the same power, and if it operates normally, the power measured by the main processor 100 and the sub-processor 200 should be the same.

The data storage module 300 stores power values stored in the main processor 100, and the control module 400 compares data of the main processor 100, the subprocessor 200, and the data storage module 300. It determines whether there is a failure and controls the operation of the digital electricity meter system according to the determination result. At this time, if the power values stored in the current time frame of the main processor 100, the subprocessor 200, and the data storage module 300 are the same, it is determined that there is no failure. If the power values are not the same, the main processor 100 or the sub It is determined that the processor 200 has failed.

Among the power values stored in the current time frame of the main processor 100, the subprocessor 200, and the data storage module 300, the power value of the main processor 100 or the power value of the data storage module 300 is the remaining two. If it is different from the power value, it is determined that the main processor 100 has failed, and if it is determined that the main processor 100 has failed, the operation of the main processor is stopped and only the subprocessor 200 is operated. Of the power values stored in the current time frame of the main processor 100, the subprocessor 200, and the data storage module 300, if the power value of the subprocessor 200 is different from the remaining two power values, the subprocessor 200 Is determined to have failed, the operation of the subprocessor 200 is stopped, and only the main processor 100 is operated.

On the other hand, Figure 4 is a block diagram schematically showing the configuration of a digital electricity meter system according to another embodiment of the present invention. 4, in addition to the controller 410, the display unit 420 and the communication device 430 are configured in the control module 400. In this case, when the main processor 100 is determined to be a failure, the operation of the main memory 150 may be completely stopped, and only the subprocessor 200 and the control module 400 may serve as electricity meters.

Hereinafter, a power value storing method of the main processor 100, the subprocessor 200, and the data storage module 300 will be described in detail with reference to FIGS. 1 and 2.

The analog values of the voltages and currents detected by the voltage detector 110 and the current detector 120 of the main processor 100 are converted into digital values by the analog / digital converter 130 and calculated as power values by the signal calculator 142. The power is measured for each time frame. Specifically, the power values are t ₀ , t ₁ , t ₂ , t ₃ It can be measured at a time interval of ... and one time unit can be defined as a time frame. Here, the power value A measured by the main processor 100 corresponding to each time frame is M ₀ , M ₁ , M ₂ , M ₃ as shown in FIG. 2. Is defined as

Similarly, the analog values of the voltage and current detected by the voltage detector 210 and the current detector 220 of the subprocessor 200 are converted into digital values by the analog-to-digital converter 230 to be powered by the signal calculator 240. It is calculated as a value, and power is measured for each time frame. These power values are t ₀ , t ₁ , t ₂ , t ₃ It can be measured at a time interval of ... and one time unit can be defined as a time frame. Here, the power value B measured by the subprocessor 200 corresponding to each time is S ₀ , S ₁ , S ₂ , S ₃ as shown in FIG. 2. ...to Is defined.

The data storage module 300 stores the power value stored in the main processor 100. The power value measured in the previous time frame is converted into the power value of the current time frame of the data storage module 300 in the main processor 100. Save as (C).

Referring to FIG. 2, in the time frame corresponding to t ₀ , the power value A of the main processor 100 is measured as M ₀ , and the power value B of the subprocessor 200 is measured as S ₀ . do. In the time frame corresponding to t ₁ , the power value A of the main processor 100 is measured as M ₁ , and the power value B of the subprocessor 200 is measured as S ₁ . Meanwhile, the power value C stored in the data storage module 300 in the time frame corresponding to t ₁ is stored as the power value A of the main processor 100 in the time frame corresponding to t ₀ , the previous frame. M ₀ is stored.

Therefore, in the time frame corresponding to t ₁ , the power values A, B, and C stored in the main processor 100, the subprocessor 200, and the data storage module 300 are M ₁ , S ₁ , and M _0, respectively. .

When the main processor 100 and the subprocessor 200 operate normally, M ₁ , which are power values A, B, and C stored in the main processor 100, the subprocessor 200, and the data storage module 300, respectively, S ₁ and M ₀ must be the same. If the three power values are not the same, it may be determined that the main processor 100 or the subprocessor 200 has failed.

Hereinafter, a failure detection method of a digital electricity meter according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3. 3 is a flowchart illustrating a failure detection method of a digital electricity meter according to an embodiment of the present invention.

1 to 3, the power value A of the main processor 100 and the power value B of the subprocessor 200 are measured in a time frame t _o (S310). Since it is the first time frame, no data is stored in the data storage module 300. In this case, a power value based on the data storage module 300 may be set.

Subsequently, the power value A of the main processor 100 and the power value B of the subprocessor 200 are measured in the t _n time frame, and the power value C of the data storage module 300 is t _{n −.} The power value A of the main processor 100 is substituted in _one time frame (S320).

Subsequently, in the t _n time frame that is the current time frame, the power value A of the main processor 100, the power value B of the subprocessor 200, and the power value C of the data storage module 300 are the same. Check whether or not (S330).

In the t _n time frame, when the power value A of the main processor 100, the power value B of the subprocessor 200, and the power value C of the data storage module 300 are the same, the main processor 100. The power value A is displayed on the display unit 160 of the electricity meter and the step S320 is repeated (S335).

In the t _n time frame, when the power value A of the main processor 100, the power value B of the subprocessor 200, and the power value C of the data storage module 300 are not the same, the subprocessor It is checked whether only the power value B of 200 is different from other values (S340).

When only the power value B of the subprocessor 200 is different from the other values, it may be determined that the subprocessor 200 has failed. Then, the subprocessor 200 is stopped and displayed on the display unit 160 as the power value A of the main processor 100 (S350). In addition, the user or the administrator is notified that the subprocessor 200 is broken so that it can be repaired.

When only the power value B of the subprocessor 200 is not different from other power values, only the power value A of the main processor 100 is different from other power values, and the power value of the data storage module 300 is different. Only (C) can be distinguished from other power values. In both of these cases, it means that the power value measured in the main processor 100 has a problem. Therefore, the main processor 100 is stopped and displayed on the display unit 160 as the power value B of the subprocessor 200 (S360). In addition, the main processor 100 to inform the user or administrator that the failure is to be repaired.

According to the digital electricity meter system and the fault detection method of the digital electricity meter according to an embodiment of the present invention, the power value is stored in three areas and the three values are compared to determine whether the system is faulty. Therefore, it is possible to detect whether or not the digital electricity meter has failed in real time.

In addition, since the main processor 100 and the sub-processor 200 are provided, when one of them fails, the other can perform power measurement. Thus, the system can operate without a gap of power measurement. On the other hand, in the digital electricity meter system and the failure detection method of the digital electricity meter according to an embodiment of the present invention, the main processor 100 is not simply three, but is configured simply by a configuration related to the measurement of the power amount in the main processor 100. By configuring the subprocessor 200 and the data storage module 300 that performs only the data storage function, the three values can be compared and failures can be determined, while the cost can be minimized and the configuration can be simplified.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be understood. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10: digital electricity meter system 20: distribution network
100: main processor 200: subprocessor
300: data storage module 400: control module

Claims (14)

A main processor and a subprocessor which detect the voltage and the current of the distribution network and measure the power for each time frame;
A data storage module for storing a power value measured in a previous time frame of the main processor as a power value of a current time frame;
And a control module comparing the power values stored in the current time frame of the main processor, the subprocessor, and the data storage module to determine whether the main processor and the subprocessor have failed.
The digital power meter system determines that there is no failure when the stored power values are the same in the current time frame of the main processor, the subprocessor, and the data storage module. If the power values are not the same, the digital power meter system determines that the main processor or the subprocessor has failed. . The method of claim 1,
If the power value of the main processor or the power value of the data storage module is different from the remaining two power values among the power values stored in the current time frame of the main processor, the subprocessor, and the data storage module, the main processor may fail. Digital electricity meter system judged to be. The method of claim 2,
And determining that the main processor has failed, stopping the operation of the main processor and operating only the subprocessor. The method of claim 1,
And among the power values stored in the current time frame of the main processor, the subprocessor, and the data storage module, determining that the subprocessor has failed when the power value of the subprocessor is different from the remaining two power values. The method of claim 4, wherein
And if it is determined that the subprocessor has failed, stopping the operation of the subprocessor and operating only the main processor. The method of claim 1,
The configuration of the sub-processor includes only a part of the configuration of the main processor, the digital power meter system including only a portion of the power calculation and storage of the configuration of the main processor. The method of claim 1,
And said main processor and said subprocessor each comprise an analog-to-digital converter. Measuring power of a power distribution network by a time frame in a main processor and a subprocessor;
Storing, by a data storage module, a power value measured in a previous time frame of the main processor as a stored value of a current time frame;
And comparing the power values stored in the current time frame of the main processor, the subprocessor, and the data storage module to determine whether the main processor and the subprocessor have failed.
When the power value stored in the current time frame of the main processor, the sub-processor and the data storage module is the same, it is determined that there is no failure. If the power values are not the same, the digital power meter determines that the main processor or the sub-processor failed Fault detection method. The method of claim 8,
If the power value of the main processor or the power value of the data storage module is different from the remaining two power values among the power values stored in the current time frame of the main processor, the subprocessor, and the data storage module, the main processor may fail. And determining that the main processor has failed, stopping the operation of the main processor and operating only the subprocessor. The method of claim 8,
Among the power values stored in the current time frame of the main processor, the subprocessor, and the data storage module, if the power value of the subprocessor is different from the remaining two power values, the subprocessor is determined to be out of order. A failure detection method of a digital wattmeter for stopping operation and operating only the main processor. Measuring power of the power distribution network in the main processor and the subprocessor at a first time;
Measuring power of a power distribution network in a main processor and a sub-processor at a second time, and storing the power value measured at a first time of the main processor as a power value of a second time of a data storage module;
And comparing the power values stored in the main processor, the subprocessor, and the data storage module at the second time to determine whether the main processor and the subprocessor have failed.
If the power values stored in the main processor, the subprocessor and the data storage module are the same at the second time, it is determined that there is no failure. If the power values are not the same, the digital power meter determines that the main processor or the subprocessor has failed. Fault detection method. 12. The method of claim 11,
In the determining of the failure of the main processor and the sub-processor, if it is determined that there is no failure,
Measuring power of a power distribution network in a main processor and a sub-processor at a third time, and storing the power value measured at a second time of the main processor as a power value of a third time of a data storage module; And
And comparing the power values stored in the main processor, the subprocessor, and the data storage module at the third time, and determining whether the main processor and the subprocessor have failed. 12. The method of claim 11,
If the power value of the main processor or the power value of the data storage module is different from the remaining two power values among the power values stored in the current time frame of the main processor, the subprocessor, and the data storage module, the main processor may fail. And determining that the main processor has failed, stopping the operation of the main processor and operating only the subprocessor. 12. The method of claim 11,
Among the power values stored in the current time frame of the main processor, the subprocessor, and the data storage module, if the power value of the subprocessor is different from the remaining two power values, the subprocessor is determined to be out of order. A failure detection method of a digital wattmeter for stopping operation and operating only the main processor.

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