KR101864626B1 - Calibration factor management system and calibration factor management method for power distribution switchgear - Google Patents

Abstract

The present invention relates to a management apparatus which can check abnormal calibration factors and manage the calibration factors in a convenient and stable manner. According to an embodiment of the present invention, the calibration factor management apparatus of a power distribution apparatus includes a main module including a first volatile memory for storing calibration factors, a first non-volatile memory storing the calibration factors, and a first processor for computing the calibration factors and storing the calibration factors to the first volatile memory and the first non-volatile memory; and an input/output module which can be connected to the main module through signals and communicate with the main module, and include a second volatile memory for storing the calibration factors, a second non-volatile memory for storing the calibration factors, and a second processor for computing the calibration factors, storing the calibration factors in the second volatile memory and the second non-volatile memory, and controlling the data of the stored calibration factors to be transmitted to the main module.

Description

TECHNICAL FIELD [0001] The present invention relates to a calibration factor management apparatus and a management method for a power distribution device,

The present invention relates to a management device and a management method for managing a correction factor (hereinafter referred to as a calibration factor) for a detected electricity quantity such as a detected voltage or current of a power distribution device.

A power distribution device, such as a load break switch, is a power device that distributes the power distribution power supplied through the ground to a plurality of load side branch circuits.

Such a load switch has three positions: a closed position for connecting the branch circuits to the power supply side, an open position for disconnecting the power supply side from the power supply side, and a grounding position for grounding, and is also called a 3 position switch.

Such a load switch comprises a main circuit switching mechanism, a plurality of main circuit bushings (three bushings are provided for each branch circuit), a voltage transformer (commonly referred to as a PT) And a current transformer (generally abbreviated as CT), a controller, and an integrated terminal device.

With regard to the construction of such a load switch, reference can be made to the following patent documents filed and published by the applicant of the present invention.

(Patent Document 1) KR10-2010-0007231 A

The main circuit device includes a plurality of (for example, four) switching mechanisms for opening / closing the branch circuit to the three positions and an actuator for providing a driving force to the switching mechanism.

The plurality of main circuit bushings are output terminal portions of a plurality of main circuit devices to which lines for power take-off of each branch circuit are connected.

The voltage transformer measures the voltage applied to the load switch and is provided at the bottom of the load switch.

The current transformer is installed around the main circuit bushing to detect the current of each branch circuit.

The controller includes a communication unit operable to communicate with an upper level control device at a remote location, and an operation control unit.

The integrated terminal unit is a device for remotely controlling and monitoring the operation of the load switch and the line condition.

The present invention relates to such integrated terminal devices, and more particularly to management of a calibration factor (correction coefficient) of electricity amount measurement data in one main module included in the integrated terminal device and a plurality of input / output modules for each branch circuit.

A prior art relating to a calibration factor management apparatus and method of such an integrated terminal apparatus will be described with reference to Figs. 1 and 2. Fig.

2, a configuration for detecting the amount of electric energy, that is, the voltage and the current, of electric energy supplied through the power supply side power distribution line 41 is a voltage transformer (commonly referred to as PT) 52, A current transformer (generally abbreviated as CT) 51, and a controller 110 of the load switch.

The actual electric quantity of the electric energy supplied through the power supply side power distribution line 41 is a voltage of 13,200 V and a current of 400 A and the voltage transformer 52 and the current transformer 51, A voltage of 4 V and a current of 400 mA which can be processed by a processor, that is, a microcomputer / microprocessor, through the control unit 110 of the integrated terminal device 100 Can be provided.

1, includes one main module 10 and a plurality of input / output modules 20 for each branch circuit, as shown in FIG.

The main module 10 and the plurality of input and output modules 20 are each composed of a printed circuit board in the form of a card and are parallel to each other, collectively referred to as a back plain connector (or back plane) And can be connected to each other by a connector.

The main module 10 and the plurality of input / output modules 20 each include an analog-to-digital converter (not shown), and the voltage 4V is converted into a digital conversion value of 12,000 V and recognized.

Therefore, as can be seen from FIG. 1 or 2, the actual voltage 13,200 V according to the amount of electricity supplied (applied) to the load switch through the power supply side power distribution line 41 and the digital conversion recognition value Failure to correct the difference will result in errors in monitoring and control of the distribution line, resulting in loss of reliability.

In order to correct the difference between the actually applied voltage and the conversion recognition value, the calculation and storage instruction of the calibration factor is sent to the main module 10 and the plurality of input / output modules 20 via the computer 30, For example, an actual voltage of 13,200 V, supplied to (applied to) the load switch by way of a switch (not shown).

The processors included in the main module 10 and the plurality of input / output modules 20, that is, the first processor 10c and the second processor 20c, respectively store the actual electricity quantity data provided by the computer 30, Based on the amount of electricity detected through the current transformer 51 or the voltage transformer 52 and digitally converted by the analog-digital converter included in the main module 10 and the plurality of input / output modules 20, 1) can calculate the calibration factor (correction coefficient).

  When the actual applied electricity quantity of 13,200 V and the digital conversion recognized electricity quantity of 12,000 V are substituted into the above equation, the calibration factor is calculated to be 1.1.

The calculated calibration factors are stored in a volatile memory provided in the main module 10, a volatile memory provided in the plurality of input / output modules 20, and a nonvolatile memory, and the calibration factor is multiplied And is used to accurately recognize the amount of electricity actually applied.

The main module 10 has a first volatile memory 10a as a volatile memory and does not have a nonvolatile memory.

Each of the plurality of input / output modules 20 includes a second volatile memory 20a as a volatile memory and a second nonvolatile memory 20b as a nonvolatile memory.

However, the calibration factor management apparatus and method according to the related art as described above have the following problems.

That is, if the calibration factor calculating function is performed in a state where there is no applied electric quantity, a wrongly calculated calibration factor, for example, O (zero) is stored and the electric quantity applied to the power distributing device (load switch) will be.

In addition, although the manufacturer of the power distribution apparatus having the integrated terminal apparatus stores the normal calibration factor before shipping the product at the factory, the data of the calibration factor stored due to the abnormal operation of the nonvolatile memory, If it is changed, it is inevitable to recalculate and store the calibration factor in the field.

However, it is difficult to block the distribution line already in use and to calculate the calibration factor again. Even if the distribution line can be shut off, a current or voltage application device is connected to the main circuit bushing or voltage transformer for each branch circuit, It is very troublesome to apply the electricity quantity of the distribution line.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a management device capable of identifying an abnormal calibration factor and managing the calibration factor simply and stably.

Another object of the present invention is to provide a management method for identifying an abnormal calibration factor and managing the calibration factor simply and stably.

It is an object of the present invention to provide a calibration factor management device for a power distribution device,

A first nonvolatile memory for storing the calibration factor; a first processor for calculating the calibration factor and storing the calibration factor in a first volatile memory and a first nonvolatile memory; a second volatile memory for storing a calibration factor; A main module having a PROCESSOR; And

A second nonvolatile memory that is connected to the main module and is capable of communicating with the main module and stores a calibration factor, a second nonvolatile memory that stores a calibration factor, and a second nonvolatile memory that calculates a calibration factor, And a second processor for storing the calibration factor data in a nonvolatile memory and controlling the transmission of the data of the calibration factor stored in the nonvolatile memory to the main module, wherein the calibration factor management device comprises: .

According to a preferred aspect of the present invention, an apparatus for managing a calibration factor of a power distribution apparatus according to the present invention is provided, which is communicatively connected to the main module, for transmitting a calibration factor stored in a first nonvolatile memory and a calibration factor stored in a first volatile memory In response to the command signal, data of a calibration factor transmitted from the first processor of the main module by reading from the first nonvolatile memory and data of the calibration factor transmitted by the first processor of the main module Further comprising a computer for displaying the data of the calibration factor read from the first volatile memory and transmitted thereon for comparison.

According to another preferred embodiment of the present invention, the data of the calibration factor transmitted from the first processor of the main module by reading from the first volatile memory is the data of the calibration factor stored in the second nonvolatile memory of the input / output module , The data of the calibration factor that the first processor of the main module reads from and transmits to the first non-volatile memory is the data of the calibration factor stored in the first non-volatile memory of the main module.

According to another preferred embodiment of the present invention, the first processor of the main module or the second processor of the input / output module is configured to compare the first data of the calibration factor stored in the first nonvolatile memory of the main module with the first data of the input / Wherein at least one of the second data of the calibration factor stored in the second non-volatile memory of the module is not zero and at least one of the first data and the second data is not corrupted, And to store the normal data among the first data and the second data in the nonvolatile memory storing the abnormal data if the data do not coincide with each other.

According to another preferred embodiment of the present invention, the first processor of the main module or the second processor of the input / output module is configured to compare the first data of the calibration factor stored in the first nonvolatile memory of the main module with the first data of the input / And if the second data of the calibration factor stored in the second nonvolatile memory of the module is all zero or all are corrupted, the calibration factor is newly calculated.

It is another object of the present invention to provide a method of managing a calibration factor of a power distribution device, the method comprising: a first operation step of transmitting data of a second calibration factor stored in a nonvolatile memory of an input / output module to a volatile memory of the main module and storing the data; And

The first data of the second calibration factor stored in the volatile memory of the main module and the second data of the first calibration factor stored in the nonvolatile memory of the main module are transmitted to the computer so that the first data and the second data And a second operation step of displaying the data on the display unit of the computer so that the value of the data and the damage of the data can be confirmed.

According to still another aspect of the present invention, there is provided a method of managing a calibration factor of a power distribution device according to the present invention, when a first data and a second data do not match, the first data and the second data are not zero Output module or the non-volatile memory of the main module in which the data whose data is not damaged is 0 (zero) as the normal calibration data or the abnormal data in which the data is damaged has been stored.

According to another preferred embodiment of the present invention, a method of managing a calibration factor of a power distribution device according to the present invention is a method of managing a calibration factor of a power distribution device according to the present invention, wherein the first data and the second data are both zero, Output module and a calibration factor recalculation step of newly calculating a calibration factor by the processor of the main module and storing the calibration factor in the nonvolatile memory of the input / output module or the main module.

The calibration factor management apparatus for a power distribution apparatus according to the present invention includes a main module and an input / output module, and the main module includes a first volatile memory and a first nonvolatile memory for storing calibration factors, A calibration factor may be stored in a non-volatile memory, and a calibration factor may be calculated by a first processor and stored in a first volatile memory and a first non-volatile memory, the input / output module including a second volatile memory storing a calibration factor, Volatile memory so that the calibration factor can be preserved in the second non-volatile memory even if the power supply is interrupted, and the calibration factor can be calculated by the second processor and stored in the second volatile memory and the second non-volatile memory I / O module is connected to main module and signal The data of the calibration factor stored in the second nonvolatile memory of the input / output module can be transferred to the main module.

Since the calibration factor management apparatus of the power distribution apparatus according to the present invention further includes a computer, the calibration factor management apparatus is communicatively connected to the main module and instructs transmission of a calibration factor stored in the first nonvolatile memory and a calibration factor stored in the first volatile memory Wherein the first processor of the main module reads the data of the calibration factor transmitted from the first non-volatile memory in response to the command signal, It is possible to obtain an effect that the data of the calibration factor read from the volatile memory and transmitted can be displayed so as to be comparable.

The calibration factor management device of the power distribution device according to the present invention is characterized in that the data of the calibration factor which the first processor of the main module reads from the first volatile memory and transfers is stored in the second nonvolatile memory of the input / And the data of the calibration factor that the first processor of the main module reads from and transmits to the first nonvolatile memory is the data of the calibration factor stored in the first nonvolatile memory of the main module, The calibration factor stored in the second nonvolatile memory of the input / output module and the data of the calibration factor stored in the first nonvolatile memory of the main module are obtained through a computer connected to the main module through the first volatile memory and compared with each other Identifiable It can be obtained with.

The first processor of the main module or the second processor of the input / output module may be configured to compare the first data of the calibration factor stored in the first nonvolatile memory of the main module At least one of the first data and the second data of the calibration factor stored in the second nonvolatile memory of the input / output module is not zero, or at least one of the first data and the second data is not damaged, If the data and the second data do not coincide with each other, it is determined that the first data and the second data are abnormal, and the normal data of the other module The main module) and reads the non-volatile memory from the non-volatile memory The data on the side having the data of the abnormality calibration factor among the main module and the input / output module is replaced with the data on the side having the data of the normal calibration factor and the data on the side having the data of the abnormality calibration factor is stored There is a recovery effect.

The first processor of the main module or the second processor of the input / output module may be configured to compare the first data of the calibration factor stored in the first nonvolatile memory of the main module And the second data of the calibration factor stored in the second nonvolatile memory of the input / output module are both zero or all damaged, the calibration factor is newly calculated. Therefore, When all of the factor data is in an abnormal state, a calibration factor is newly computed and stored, so that the calibration factor data of the main module and the input / output module can be recovered.

A calibration factor management method for a power distribution device according to the present invention includes a first operation step of transmitting data of a second calibration factor stored in a nonvolatile memory of an input / output module to a volatile memory of a main module and storing the data; And a second data of a second calibration factor stored in a volatile memory of the main module and a second data of a first calibration factor stored in a nonvolatile memory of the main module, And a second operation step of displaying the data on the display unit of the computer so that the value of the data and the damage of the data can be checked, thereby obtaining the effect that the user can compare and check the data of the calibration factor of the main module and the input / output module .

A method of managing a calibration factor of a power distribution apparatus according to the present invention is a method of managing data of a first data and a second data that is not zero and data is not corrupted as normal calibration data Output module or the non-volatile memory of the main module storing the abnormal data, which is 0 (zero) or the data is damaged. Therefore, it is possible to prevent the unauthorized calibration factor of the main module and the input / The data on the side having the data of the abnormal calibration factor can be recovered by replacing the data with the data on the side having the data of the normal calibration factor.

A method of managing a calibration factor of a power distribution device according to the present invention is a method for managing a calibration factor of a power distribution device in a case where both the first data and the second data are zero or both the first data and the second data are damaged, And a calibration factor recalculation step of newly calculating a calibration factor and storing it in the nonvolatile memory of the input / output module or the main module. Therefore, when all the calibration factor data stored in the main module and the input / output module are in an abnormal state Calibration factor data of the main module and the input / output module can be recovered by newly calculating and storing the calibration factor.

FIG. 1 is a block diagram showing a configuration of a calibration factor management apparatus of a power distribution apparatus according to the related art,
2 is a system configuration diagram showing a system configuration of a power distribution apparatus including a calibration factor management apparatus according to the prior art or the present invention,
3 is a block diagram showing the configuration of a calibration factor management apparatus of a power distribution apparatus according to a preferred embodiment of the present invention,
4 is a flowchart illustrating a method of managing a calibration factor of a power distribution device according to an exemplary embodiment of the present invention.

The above and other objects, features and advantages of the present invention will become more apparent from the following description of the preferred embodiments of the present invention with reference to the accompanying drawings.

3, the apparatus for managing calibration factor of power distribution apparatus according to the preferred embodiment of the present invention includes one main module 10 and a plurality of input / output modules 20.

One main module 10 and a plurality of input / output modules 20 are formed as card-type printed circuit boards, and are connected to each other by a parallel connector commonly referred to as a backplane connector 15 .

The main module 10 and the plurality of input / output modules 20 each include an analog-to-digital converter (not shown).

One main module 10 may transmit data including command data or receive data from the plurality of input / output modules 20 to the plurality of input / output modules 20 through the backplane connector 15.

One main module 10 includes a first volatile memory 10a, a first nonvolatile memory 10b and a first processor 10c.

The first volatile memory 10a and the first non-volatile memory 10b store calibration factors.

The first volatile memory 10a may be a static random access memory (SRAM), for example, which is not guaranteed to save data when power supply is interrupted.

The first nonvolatile memory 10b may be a memory capable of storing the stored data even if power supply is interrupted, for example, a Ferroelectric Random Access Memory (FRAM).

The calibration factor stored in the first volatile memory 10a and the first nonvolatile memory 10b may be calculated based on the actual amount of electricity (for example, the actual current and the actual voltage) of the power distribution apparatus provided by the computer 30, The first processor 10c calculates the actual electric quantity of the power distribution device detected by the current transformer 51 and the voltage transformer 52 and received from the control unit 110 of the load switch, 1 data of the calibration factor stored in the nonvolatile memory 10b.

The first processor 10c can be obtained by calculating the calibration factor by the above-described equation (1) and the processing program stored in program storage means (not shown) included in the first processor 10c.

That is, the first processor 10c calculates the calibration factor by calculating a value obtained by digitally converting the actual electricity amount by the analog-to-digital converter and the actual electricity amount (actual applied electricity amount) into the equation (1) .

The number of the plurality of input / output modules 20 is determined according to the number of the load side branching circuits connected to the load switch 110 in the power distribution device, for example, the load switch 110. The number of input / output modules 20 may be four according to one embodiment.

The plurality of input / output modules 20 are connected to the main module 10 and the backplane connector 15 through a signal connection to communicate with the main module 10.

Each of the plurality of input / output modules 20 includes a second volatile memory 20a, and a second nonvolatile memory 20b and a second processor 20c.

The second volatile memory 20a and the second nonvolatile memory 20b included in each input / output module 20 store calibration factors.

The calibration factor stored in the second nonvolatile memory 20b and the second nonvolatile memory 20b is determined by the actual amount of electric power of the power distribution device provided by the computer 30 or the voltage transformer 51 of FIG. Based on the actual electricity quantity of the power distribution apparatus detected by the power switch 52 and received from the control section 110 of the load switch, the second processor 20c calculates the second electric power consumption value of the second nonvolatile memory 20b and the second non- Of the calibration factor.

The second processor 20c can be obtained by calculating the calibration factor by a processing program stored in a program storage unit (not shown) included in the above-described equation (1) and the second processor 20c.

That is, the second processor 20c calculates the calibration factor by computing the value obtained by digitally converting the actual electricity amount by the analog-to-digital converter and the actual electricity amount (actually applied electricity amount) into the equation (1) .

In addition, the second processor 20c may control to read the data of the calibration factor stored in the second nonvolatile memory 20b and transmit the data to the main module 10 through the backplane connector 15. [

3, the apparatus for managing the calibration factor of the power distribution apparatus according to the preferred embodiment of the present invention may further include a computer 30.

The computer 30 may be a personal computer (PC), a notebook computer, a pad type computer, a portable terminal, or the like.

The computer 30 is connected to the main module 10 to receive a command signal for instructing transmission of a calibration factor stored in the first nonvolatile memory 10b and a calibration factor stored in the first volatile memory 10a, To the module (10).

In response to the command signal, the data of the calibration factor that the first processor 10c of the main module 10 reads from the first nonvolatile memory 10b and transmits to the first processor 10c The computer 30 displays the data of the two calibration factors through a display included in the computer 30 so that the data of the calibration factors read from the first volatile memory 10a can be compared with the data of the calibration factor transmitted from the first volatile memory 10a .

The data of the calibration factor that the first processor 10c of the main module 10 reads from the first volatile memory 10a and is transferred is stored in the second nonvolatile memory 20b of the input / Is the data of the calibration factor. The data of the calibration factor that the first processor 10c of the main module 10 reads from the first nonvolatile memory 10b and is transferred is stored in the first nonvolatile memory 10b of the main module 10 It is the data of the calibration factor stored.

The first data of the calibration factor stored in the first nonvolatile memory 10b of the main module 10 and the second data of the calibration factor stored in the second nonvolatile memory 20b of the input / At least one of the first data and the second data is not damaged and at least one of the first data and the second data is not damaged. If the first data and the second data do not coincide with each other, ) Or the second processor 20c of the input / output module 20 is configured to control the normal data among the first data and the second data to be stored in the nonvolatile memory storing the abnormal data.

Here, a method of determining whether the first data processor 10c of the main module 10 or the second processor 20c of the input / output module 20 discriminates normal data among the first data and the second data is as follows.

That is, in the first processor 10c of the main module 10 or the second processor 20c of the input / output module 20, when one of the first data and the second data is zero and the other is not zero, And determines the data as normal data.

Also, the first processor 10c of the main module 10 or the second processor 20c of the input / output module 20 may be configured such that if one of the first data and the second data is damaged and the other is not damaged, And determines that the data that is not normal is normal data.

When the first data 10c of the main module 10 or the second processor 20c of the input / output module 20 does not coincide with the first data and the second data, Comparing the first data with the second data, and when either one of the first data and the second data is within the range of the normal data and the other is out of the range of the normal data, As normal data.

The first processor 10c or the second processor 20c may be configured such that the first processor 10c or the second processor 20c is configured in accordance with the program stored in advance in the first processor 10c or the second processor 20c, The first processor 10c may be configured to be configured to perform the operation as described above by itself.

According to another embodiment, the computer 30 transmits a command signal to the main module 10 as instructed by the user, and transmits the command signal to the first processor 10c of the main module 10 or the input / output module 20) of the second processor 20c is configured to perform the operation as described above (i.e., control to store the normal data of the first data and the second data in the nonvolatile memory storing the abnormal data) Can be implemented.

The first data of the calibration factor stored in the first nonvolatile memory 10b of the main module 10 and the second data of the calibration factor stored in the second nonvolatile memory 20b of the input / The first processor 10c of the main module 10 or the second processor 20c of the input / output module 20 is configured to newly calculate the calibration factor when both are zero or all are damaged.

Here, the method of newly calculating the calibration factor is the same as the calculation method of the above-described calibration factor in relation to the equation (1), so that redundant description will be omitted.

At least one of the first data of the calibration factor stored in the first nonvolatile memory of the main module and the second data of the calibration factor stored in the second nonvolatile memory of the input / output module is zero Or if at least one of the first data and the second data is not damaged or if the first data and the second data do not coincide with each other, it is determined that the first data and the second data are abnormal, If the partner module (the module to which the user belongs is the main module, the input / output module, or the module to which the user belongs is the input / output module, the main module) is read and stored in the nonvolatile memory storing the abnormal data.

In this case, the first processor 10c or the second processor 20c may be configured as described above in accordance with the program stored in advance in the first processor 10c or the second processor 20c according to the embodiment I. E., The first processor or the second processor, computes a calibration factor) may be implemented to be implemented.

According to another embodiment, the computer 30 transmits a command signal to the main module 10 as instructed by the user, and transmits the command signal to the first processor 10c of the main module 10 or the input / output module 20 may be implemented such that the second processor 20c of the processor 20 is configured to perform the operations as described above (i.e., the first processor or the second processor computes a new calibration factor).

The operation of the calibration factor managing method of the power distribution device or the calibration factor managing device of the power distribution device according to the preferred embodiment of the present invention will be described with reference to FIG. 4 mainly and with reference to FIGS.

The first operation (first operation step) is to transfer the data of the second calibration factor stored in the nonvolatile memory 20b of the input / output module 20 to the volatile memory 10a of the main module 10 and store the data.

This operation is performed to check and compare the data of the first calibration factor stored in the nonvolatile memory 10b of the main module 10 and the data of the second calibration factor stored in the nonvolatile memory 20b of the input / It can be seen as a preparation action.

The second operation (the second operation step) is performed by the first data of the second calibration factor stored in the volatile memory 10a of the main module 10 and the first data of the second calibration factor stored in the nonvolatile memory 10b of the main module 10 The second data of the factor is transmitted to the computer 30 and displayed on the display unit of the computer 30 so that the user can check the value of the first data and the second data and whether the data is damaged.

This operation is performed by comparing the data of the second calibration factor stored in the nonvolatile memory 20b of the input / output module 20 with the data of the first calibration factor stored in the nonvolatile memory 10b of the main module 10 The first data and the second data are transmitted to the computer 30 through the main module 10 to check whether the values of the first data and the second data are normal and whether the data is damaged, It means an operation of providing the user's judgment basis information so that the data values can be compared.

This second operation is performed in such a manner that the first data of the second calibration factor stored in the volatile memory 10a of the main module 10 and the second data of the second calibration factor stored in the nonvolatile memory 10b of the main module 10 The first processor 10c of the main module 10 checks whether the values of the first data and the second data are normal and whether the data is damaged or not according to the processing program pre- The first processor 10c may be replaced with an operation of providing the first data and the second data to the first processor 10c so that the values of the first data and the second data can be compared. At this time, the second operation may be performed according to a predetermined operation cycle (for example, once every two hours or once a day) in the processing program.

In the third operation (third operation step), the first data of the second calibration factor stored in the volatile memory 10a of the main module 10 is stored in the nonvolatile memory 10b of the main module 10, The second data of the first calibration factor stored in the volatile memory 20a of the I / O module 20 is stored in the nonvolatile memory 20b of the I / O module 20. [

In the third operation, when either one of the calibration factor data stored in the nonvolatile memory of the main module 10 or the calibration factor data stored in the nonvolatile memory of the input / output module 20 is abnormal and the other is normal, Can be regarded as an operation of replacing the data of the calibration factor that is the normal calibration factor with the data of the normal calibration factor.

Here, a state in which the data is abnormal can be interpreted as meaning that the value is zero (0) or the data is damaged (aka broken state).

The input / output module 20 and the processor of the main module 10, that is, the second processor 20c or the first processor 10c newly calculate the calibration factor, respectively, and the input / output module 20 Or the non-volatile memory of the main module 10 (i.e., the second non-volatile memory or the first non-volatile memory).

The operation of the management device and the method of managing the calibration factor of the power distribution device according to the preferred embodiment of the present invention will be described with reference to FIG. 4 and supplementarily with FIG. 2 to FIG.

First, the first operation (first operation step) is executed in step S1 in Fig.

As described above, in step S1, the second processor 20c of the input / output module 20 transfers the data of the second calibration factor stored in the nonvolatile memory 20b of the input / output module 20 to the volatile To the memory 10a, and the first processor 10c of the main module 10 stores the data of the second calibration factor in the volatile memory 10a.

According to one embodiment, the first processor 10c of the main module 10 and the second processor 20c of the input / output module 20 are controlled in accordance with a program previously stored in the first processor 10c or the second processor 20c, May be configured to perform the first operation by itself every predetermined period.

The computer 30 transmits a command signal to the main module 10 as instructed by the user via the computer 30 while the computer 30 is connected to the main module 10 according to another embodiment, The first processor 10c of the main module 10 and the second processor 20c of the input / output module 20 may be configured to perform the first operation in response to the signal.

Next, the second operation (operation 2) is executed in step S2.

As described above, in step S2, the first data of the second calibration factor stored in the volatile memory 10a of the main module 10 and the first data of the second calibration factor stored in the nonvolatile memory 10b of the main module 10 The second data of the stored first calibration factor is transmitted to the computer 30 and displayed on the display unit of the computer 30 so that the user can check the value of the first data and the second data and whether the data is damaged.

The first processor 10c of the main module 10 and the second processor 10b of the input / output module 20 are controlled in accordance with another program stored in the first processor 10c or the second processor 20c in step S2 20c may be configured to perform the second operation of step S2. That is, according to another embodiment, in step S2, the first processor 10c of the main module 10 reads the first data of the second calibration factor stored in the volatile memory 10a and the first data of the main module 10 The second data of the first calibration factor stored in the nonvolatile memory 10b of the second memory unit 10b.

The second operation (operation 2) may be composed of the following three detailed steps (operation).

That is, steps S2-1, S2-2, and S2-3 are the same.

In step S2-1, the user confirms whether the values of the first data and the second data displayed through the display unit of the computer 30 are both O (zero) according to one embodiment.

The first processor 10c of the main module 10 stores the first data of the second calibration factor stored in the volatile memory 10a and the first data of the main module 10 stored in the volatile memory 10a according to the pre- The second data of the first calibration factor stored in the nonvolatile memory 10b of the first calibration factor is 0 (zero).

In step S2-1, if both the first data and the second data are O (zero), the process proceeds to step S4 described later. If at least one of the first data and the second data is not O (zero) .

In step S2-2, according to one embodiment, the user confirms whether the values of the first data and the second data displayed through the display unit of the computer 30 are both damaged (aka data is broken).

The first processor 10c of the main module 10 stores the first data of the second calibration factor stored in the volatile memory 10a and the second data of the main module 10 ) Of the first calibration factor stored in the nonvolatile memory 10b of the first calibration factor is damaged (that is, the data is broken).

In step S2-2, if both the first data and the second data are damaged, the process proceeds to step S4 described later. If at least one of the first data and the second data is not damaged, the process proceeds to step S2-3.

In step S2-3, the user checks whether the values of the first data and the second data displayed on the display unit of the computer 30 are inconsistent with each other.

The first processor 10c of the main module 10 stores the first data of the second calibration factor stored in the volatile memory 10a and the second data of the main module 10a according to the pre- The second data of the first calibration factor stored in the nonvolatile memory 10b of the nonvolatile memory 10b are inconsistent with each other.

In step S2-3, if the first data and the second data are inconsistent with each other, the process proceeds to step S5, and if the first data and the second data coincide with each other, the process proceeds to step S3.

Step S5 is a data recovery step in which abnormal data is replaced with normal data and stored.

In step S5, if the first data and the second data do not match, the second processor 20c of the input / output module 20 or the first processor 10c of the main module 10 is 0 (zero) Output module 20 or the non-volatile memory of the main module 10 by replacing the abnormal data by normal data that is not zero (0) and is not corrupted. That is, when the first data and the second data are inconsistent, only one of the first data and the second data is normal data. For example, if the first data is abnormal, the first processor 10c of the main module 10, Transfers the second data to the input / output module 20, and stores the abnormal data in the second nonvolatile memory 20b by replacing the abnormal first data with the normal second data. Further, for example, if the second data is abnormal, the first processor 10c of the main module 10 replaces the abnormal second data with the first normal data and stores it in the first nonvolatile memory 10b.

On the other hand, step S4 is a calibration factor re-arithmetic storage step.

When both the first data and the second data are zero or both the first data and the second data are damaged, the second processor 20c of the input / output module 20 and the first processor 20c of the main module 10, The controller 10c newly calculates a calibration factor and stores it in the second nonvolatile memory 20b of the input / output module 20 or the first nonvolatile memory 10b of the main module 10. [

Since the second processor 20c of the input / output module 20 and the first processor 10c of the main module 10 calculate the calibration factor using the equation (1) as described above, A description thereof will be omitted.

On the other hand, in step S2-3, if the first data and the second data coincide with each other, the process proceeds to step S3.

In step S3, according to one embodiment, when the values of the first data and the second data displayed through the display unit of the computer 30 are equal to each other, the user determines that the two data, i.e., the first data and the second data are normal, The factor management operation can be terminated.

The first processor 10c of the main module 10 stores the first data of the second calibration factor stored in the volatile memory 10a according to the previously stored program and the first data of the second calibration factor stored in the volatile memory 10a, When the second data of the first calibration factor stored in the nonvolatile memory 10b coincide with each other, it is determined that the two data, i.e., the first data and the second data are normal, and the calibration factor management operation can be terminated.

As described above, the apparatus and method for managing calibration factor of power distribution apparatus according to the present invention can easily compare and check calibration factor data stored in main module and input / output module without blocking power distribution line in use, And the calibration factor data stored in the main module and the input / output module are all abnormal, the new calibration factor is computed and stored so as to be applied to the power distribution device (load switch) It is possible to obtain an effect that the amount of electricity to be subsequently recognized accurately.

10: main module 10a: first volatile memory
10b: first nonvolatile memory 10c: first processor
15: back plain connector
20: Input / output module (I / O module)
20a: second volatile memory 20b: second nonvolatile memory
20c: second processor 30: computer
41: Power supply side distribution line 51: Current transformer
52: voltage transformer 100: integrated terminal device

Claims (8)

1. A calibration factor management device for a distribution device,
A first nonvolatile memory for storing the calibration factor; a first processor for calculating the calibration factor and storing the calibration factor in a first volatile memory and a first nonvolatile memory; a second volatile memory for storing a calibration factor; A main module having a PROCESSOR;
A second nonvolatile memory that is connected to the main module and is capable of communicating with the main module and stores a calibration factor, a second nonvolatile memory that stores a calibration factor, and a second nonvolatile memory that calculates a calibration factor, A second processor capable of storing data in a nonvolatile memory and controlling data of a stored calibration factor to be transmitted to the main module; And
Communicably connected to the main module,
Wherein the first module of the main module transfers a calibration signal stored in the first nonvolatile memory and a command signal instructing transmission of a calibration factor stored in the first volatile memory to the main module, And a computer for comparing the data of the calibration factor read from the volatile memory and transferred, and the data of the calibration factor read by the first processor of the main module from the first volatile memory and transmitted,
The data of the calibration factor that the first processor of the main module reads from and transmits to the first volatile memory is the data of the calibration factor stored in the second nonvolatile memory of the input /
Wherein the calibration factor data read from the first nonvolatile memory by the first processor of the main module is data of a calibration factor stored by the first nonvolatile memory of the main module. Management device. delete delete The method according to claim 1,
Wherein the first processor of the main module or the second processor of the input /
At least one of the first data of the calibration factor stored in the first nonvolatile memory of the main module and the second data of the calibration factor stored in the second nonvolatile memory of the input / output module is not zero, At least one of the first data and the second data is not damaged. If the first data and the second data do not coincide with each other, the normal data among the first data and the second data is stored in a nonvolatile memory So as to control the calibration factor of the power distribution device. The method according to claim 1,
Wherein the first processor of the main module or the second processor of the input /
If the first data of the calibration factor stored in the first nonvolatile memory of the main module and the second data of the calibration factor stored in the second nonvolatile memory of the input / output module are both zero or all damaged, And calculate a calibration factor for the calibration factor of the power distribution device. A method for managing a calibration factor of a power distribution device,
A first operation step of transmitting first data of a second calibration factor stored in a nonvolatile memory of the input / output module to a volatile memory of the main module and storing the first data;
The first data of the second calibration factor stored in the volatile memory of the main module and the second data of the first calibration factor stored in the nonvolatile memory of the main module are transmitted to the computer so that the first data and the second data And displaying the data on the display unit of the computer so as to confirm whether the data is damaged or not; And
When the values of the first data and the second data are all zero or both the first data and the second data are damaged, the processor of the input / output module and the main module newly calculates a calibration factor, And a calibration factor recalculation storing step of storing the calibration factor in a non-volatile memory of the module. The method according to claim 6,
When the first data and the second data do not coincide with each other, the first data and the second data, which are not zero but are not corrupted, are stored as normal calibration data, And storing data in a non-volatile memory of the main module. delete

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