KR102130520B1 - Method And Apparatus for Relaying Measuring Information - Google Patents

Abstract

Disclosed is a method and apparatus for relaying measurement information.
This embodiment is connected between a master device for collecting data and a slave device for measuring data, to grasp the data collection cycle of the master device, to set a data collection cycle and another new data collection cycle to avoid interference or collision, Provided is a method and apparatus for relaying measurement information to collect other information in a new data collection cycle and interoperate with operators.

Description

Method and Apparatus for Relaying Measuring Information}

This embodiment relates to a method and apparatus for relaying measurement information.

The contents described below merely provide background information related to the present embodiment, and do not constitute a prior art.

In general, the meter reading method of electricity, gas, water, etc., the meter readers go directly to the meter to check the meter value, record the checked meter data manually, and input it to the computer.

The method by which the meter checks the meter directly takes not only a lot of manpower and cost, but also has a problem that it is difficult to perform the meter reading itself due to the handwriting error of the meter reader or the occupant is absent or the resident refuses to read the meter.

In the case of using a wireless remote control meter reading device to solve the above-mentioned problem, it is possible to wirelessly receive power, water usage, and the like used in a house by using communication.

In order to use RF communication, the wireless remote control meter reading device adds a wireless transceiver to a meter that detects the amount of electricity, water, gas, etc. installed on the user's side. The request is received and the usage information is transmitted wirelessly.

The conventional remote control meter reading device requests and receives the amount of power using the DLMS (Device Language Message Specification)/COSEM (Companion Specification for Energy Meters) protocol when requesting metering, and interlocks the detected power with other devices There is a problem of not being able to. In other words, the remote control reading device receives a power amount using a DLMS/COSEM protocol using a preset line, and there is a problem in that it cannot receive a service by sharing or processing data in conjunction with other devices.

This embodiment is connected between a master device for collecting data and a slave device for measuring data, to grasp the data collection cycle of the master device, to set a data collection cycle and another new data collection cycle to avoid interference or collision, The purpose of the present invention is to provide a method and apparatus for relaying measurement information that collects other information in a new data collection cycle and works with operators.

According to an aspect of the present embodiment, a master intercept unit for intercepting a power request command transmitted from a master collection device to a slave measurement device on a line and bypassing the power request command to the slave measurement device; A slave intercept unit for intercepting a power amount response signal corresponding to the power amount request command transmitted from the slave measurement device to the master collection device on a line and bypassing the power amount response signal to the master collection device; A period identification unit for determining a master request command period based on a transmission time point of the power amount request command and a reception time point of the power amount response signal; A new cycle calculating unit that calculates a new request command cycle by avoiding the master request command cycle; A slave communication unit that generates a new request command different from the power request command and transmits the new request command to the slave measurement device in the new request command cycle; And it provides a measurement information relay device, characterized in that it comprises a carrier communication unit for receiving a new response signal corresponding to the new request command from the slave measurement device to transmit to a new operator device.

According to another aspect of the present embodiment, the process of intercepting the power request command transmitted from the master collection device to the slave measurement device on the line and bypassing the power request command to the slave measurement device; Intercepting a power amount response signal corresponding to the power amount request command transmitted from the slave measurement device to the master collection device on a line and bypassing it to the master collection device; Determining a master request command period based on a transmission time point of the power amount request command and a reception time point of the power amount response signal; Calculating a new request command cycle by avoiding the master request command cycle; Generating a new request command different from the power request command and transmitting the new request command to the slave measurement device in the new request command period; And receiving a new response signal corresponding to the new request command from the slave measurement device and transmitting it to a new operator device.

As described above, according to the present embodiment, it is connected between a master device for collecting data and a slave device for measuring data, so as to grasp the data collection cycle of the master device and to avoid data interference and other collisions. It has the effect of setting the data collection cycle and collecting other information with the new data collection cycle to interwork with the operators.

1 is a block diagram schematically showing a measurement information relay system according to the present embodiment.
2 is a block diagram schematically showing a line switching circuit according to the present embodiment.
3A is a block diagram schematically showing a measurement information relay unit according to the present embodiment.
3B is a block diagram illustrating in detail a line switching circuit according to the present embodiment.
4 is a flowchart for explaining a measurement information relay method according to the present embodiment.

Hereinafter, this embodiment will be described in detail with reference to the accompanying drawings.

1 is a block diagram schematically showing a measurement information relay system according to the present embodiment.

In general, it is important for the wireless remote control meter reading device to calculate the exact time and usage in order to analyze the amount of power. For example, the wireless remote control metering device must measure the exact amount of power in 15 minute increments. The wireless remote control meter reading device stores the measured amount of power, reads the amount of power through communication, and transmits it to a preset operator server (for example, Internet communication).

However, the wireless remote control meter reading device generates a delay (±) when transmitting the measured amount of electricity through Internet communication. Therefore, it is difficult for the wireless remote control meter reading device to check the exact amount of power at the correct time due to traffic during long distance communication. However, in the measurement information relay system according to the present embodiment, the measurement information relay device 120 is installed locally to check the exact amount of power and additional information without delay.

The measurement information relay system according to the present embodiment includes a master collection device 110, a measurement information relay device 120, and a slave measurement device 130. Components included in the measurement information relay system are not necessarily limited thereto.

The master collection device 110 means an information collection device connected to the slave measurement device 130 by a communication line. The master collection device 110 transmits a power amount request command using a communication line connected to the slave measurement device 130. The master collection device 110 receives and stores the power quantity response signal corresponding to the power quantity request command from the slave measurement device 130.

Basically, the master collection device 110 detects the power meter from the slave measurement device 130 using the Device Language Message Specification (DLMS)/Companion Specification for Energy Meters (COSEM) protocol to detect power.

The master collection device 110 transmits a power amount request command to the slave measurement device 130, and receives a power amount response signal corresponding to the power amount request command from the slave measurement device 130.

Only a predetermined specific operator using the DLMS/COSEM protocol can link the master collection device 110 with the power response signal. Other operators, except for a specific preset operator, cannot interlock the master collection device 110 and the power response signal. When the measurement information relay device 120 according to the present embodiment is used, measurement information collected from the slave measurement device 130 may be interlocked with other operators except for a predetermined specific operator.

When the master collection device 110 transmits a request command for a specific measurement unit among a plurality of measurement units 131 to 139 within the power amount request command, all the measurement units 131 to 139 included in the slave measurement device 130 A request command for a specific measurement unit is received, but only a specific measurement unit among a plurality of measurement units transmits a power response signal in response to the request command.

The slave measurement device 130 means a measurement device that measures a power amount, a current, a voltage, a power factor, a loss, and the like, including a plurality of measurement units (eg, the first measurement units 131 to n-th measurement units 139). The slave measuring device 130 includes first measuring units 131 to n-th measuring units 139. The first measurement unit 131 and the nth measurement unit 139 are connected on one line connected to the master collection device 110 and the measurement information relay device 120.

The slave measurement device 130 generates a power amount response signal corresponding to the power amount request command received from the master collection device 110 and transmits it to the master collection device 110. The slave measurement device 130 generates a new response signal corresponding to the new request command received from the measurement information relay device 120 and transmits it to the measurement information relay device 120.

When the master collection device 110 transmits a power request command to the slave measurement device 130, the power request command for the ninth measurement unit 134 is carried in a packet and transmitted to the slave measurement device 130. The command for requesting the amount of power transmitted by the master collection device 110 is simultaneously transmitted to all measurement units in the slave measurement device 130.

All measurement units included in the slave measurement device 130 receive the power amount request command, but only the ninth measurement unit 134 generates a power amount response signal corresponding to the full power request command and transmits it to the master collection device 110. The slave measurement device 130 includes a plurality of measurement units 131 to 139, and the plurality of measurement units 131 to 139 are connected in series with each other.

The measurement information relay device 120 is a kind of sub information collection device, and is connected between the master collection device 110 and the slave measurement device 130 to transmit and receive signals between the master collection device 110 and the slave measurement device 130 Intercepts. After measuring the signal transmission cycle of the master collection device 110, the measurement information relay device 120 transmits other information to the slave measurement device 130 at a different cycle from the master collection device 110.

In general, when a device for relaying power is additionally connected on a connection line between the master collection device 110 and the slave measurement device 130, interference and collision between the master collection device 110 and the device for relaying power This happens.

In other words, when a device for relaying power is connected to the ends of the master collection device 110 and the slave measurement device 130, that is, the nth measurement unit, a plurality of measurement units are a device for relaying power and a master collection device ( If the request command is received from 110 simultaneously, interference or collision occurs.

When the slave measurement device 130 receives a request command from the device for relaying power and the master collection device 110 at the same time, the request cycle of the request command overlaps. Accordingly, a problem occurs that the slave measurement device 130 does not respond to all the request commands simultaneously received from the device for relaying power and the master collection device 110.

However, since the measurement information relay device 120 according to the present embodiment is connected to intercept commands or signals between the master collection device 110 and the slave measurement device 130, the master measurement device 130 collects the master Even if both the device 110 and the measurement information relay device 120 are present, no interference or collision occurs.

The measurement information relay device 120 intercepts the power request command that the master collection device 110 transmits to the slave measurement device 130 on the line, and then bypasses the power request command to the slave measurement device 130 ( Bypass).

The measurement information relay device 120 intercepts the electric power response signal corresponding to the electric power request command that the slave measuring device 130 transmits to the master collecting device 110 on the line and bypasses it to the master collecting device 110.

The measurement information relay device 120 determines the master request command period based on the transmission time of the power quantity request command and the reception time of the power quantity response signal.

The measurement information relay device 120 grasps a master request command cycle (eg, a 10 second unit cycle, a 1 minute unit cycle, and a 5 minute unit cycle) to the master collection device 110. The measurement information relay device 120 calculates a new request command cycle at a time when a master request command cycle of the master collection device 110 is avoided (for example, an 11 second unit cycle, a 1 minute 1 second unit cycle, and a 4 minute unit cycle) ( Setting).

The measurement information relay device 120 normally transmits an intercepted power request command from the master collection device 110 to the slave measurement device 130, and when a new request command is set, avoids the master request command cycle and issues a request command at a new cycle. send.

If the measurement information relay device 120 changes the master request command cycle for the master collection device 110, the new request command cycle is stopped. The measurement information relay device 120 stops a new request command cycle when the master request command cycle for the master collection device 110 is changed in order to preferentially process the master request command cycle for the master collection device 110. . The measurement information relay device 120 re- grasps the changed master request command cycle and sets a new cycle for the new request command.

The measurement information relay device 120 stops the cycle of the new request command even when the power amount response to the power request command exceeds a preset timer. The measurement information relay device 120 may divide the period in detail.

The measurement information relay device 120 generates a new request command different from the power amount request command and transmits it to the slave measurement device at a new request command cycle. The power amount request command transmitted from the master collection device 110 to the slave measurement device 130 includes only the power amount request. The new request commands include current, voltage, power factor, and loss request commands. The measurement information relay device 120 detects a new cycle and requests additional information (current, voltage, power factor, loss).

The measurement information relay device 120 receives a new response signal corresponding to a new request command command from the slave measurement device 130 and transmits it to a preset operator device. The measurement information relay device 120 may process a new response signal for a suitable use in a demand resource trading market (DR: Demand Response), EMS (Energy Management System), BEMS (Building Energy Management System) and provide it as a new operator device. have.

The measurement information relay device 120 connects a communication line between the master collection device 110 and the slave measurement device 130 to grasp the request cycle of the master collection device 110, set a different cycle by avoiding the request cycle, and , Requests a new command to the slave measurement device 130 at another cycle.

2 is a block diagram schematically showing a line switching circuit according to the present embodiment.

The measurement information relay device 120 according to the present embodiment includes a line switching circuit unit 210 and a measurement information relay unit 220.

The line switching circuit unit 210 is implemented as a hardware safety circuit. The line switching circuit unit 210 is a circuit that directly connects the master collection device 110 to the slave measurement device 130 when a problem occurs in the measurement information relay device 120.

The line switching circuit unit 210 transfers the line so that the master collection device 110 and the slave measurement device 130 are automatically connected by local hardware interlock when a problem such as power failure, CPU malfunction, adapter failure, or power failure occurs. do.

The line switching circuit unit 210 allows the master collection device 110 and the slave measurement device 130 to communicate through the measurement information relay unit when the measurement information relay unit 220 operates normally.

When the measurement information relay unit 220 operates abnormally (power off, watchdog), the line switching circuit unit 210 switches the line so as to pass through the contact b and the contact b`, and the master collection device 110 and the slave measurement device 130 ).

The measurement information relay unit 220 analyzes the periodicity of the master collection device 110 to perform additional local communication with the slave measurement device 130 in a time range without interference, and when an abnormal operation occurs, the master collection device 110 ) Stops local communication, and controls the line switching circuit 210 so that the master collection device 110 and the slave measurement device 130 first communicate.

The line switching circuit unit 210 internally branches into two lines to switch the lines according to normal or abnormal conditions.

When a problem occurs in the measurement information relay unit 220, the line switching circuit unit 210 switches the contact c, the contact c` to one of the branched lines (contact b-contact b`), and the master collection device 110 Is to directly communicate with the slave measurement device 130.

The line switching circuit unit 210 switches the contact c and the contact c` to one of the lines (contact a-contact a`) that is branched during normal operation of the measurement information relay unit 220 so that the master collection device 110 The measurement information relay unit 220 communicates between the slave measurement devices 130.

3A is a block diagram schematically showing a measurement information relay unit according to the present embodiment.

The measurement information relay device 120 according to the present embodiment includes a line switching circuit unit 210 and a measurement information relay unit 220.

The measurement information relay unit 220 according to this embodiment includes a master intercept unit 312, a slave intercept unit 314, a period grasping unit 320, a new period calculating unit 330, a slave communication unit 340, and an operator communication unit. 350. The components included in the measurement information relay unit 220 are not necessarily limited thereto.

Each component included in the measurement information relay unit 220 may be connected to a communication path connecting a software module or a hardware module inside the device to operate organically with each other. These components communicate using one or more communication buses or signal lines.

Each component of the measurement information relay unit 220 illustrated in FIG. 3A refers to a unit that processes at least one function or operation, and may be implemented by a software module, a hardware module, or a combination of software and hardware.

The master intercept unit 312 intercepts the electric power request command that the master collection device 110 transmits to the slave measurement device 130 on the line, and then bypasses the electric power request command to the slave measurement device 130 (Bypass) ). One side of the master intercept portion 312 is connected to the output terminal of the master collection device 110, and the other side of the master intercept portion 312 is connected to the input terminal of the slave measuring device.

The slave intercept unit 314 intercepts the electric power response signal corresponding to the electric power request command that the slave measuring device 130 transmits to the master collecting device on the line and bypasses it to the master collecting device 110. One side of the slave intercept unit 314 is connected to the input terminal of the master collection device 110, and the other side of the slave intercept unit 314 is connected to the output terminal of the slave measurement device 130.

The period determining unit 320 determines the master request command period based on the transmission time of the power amount request command and the reception time of the power amount response signal. The period determining unit 320 analyzes the periodicity of the master collection device 110 based on the transmission time of the power request command and the reception time of the power response signal, so that the communication with the slave measurement device 130 is performed in a time range without interference. Calculate the new request command cycle.

The period determining unit 320 checks the entire time unit of the transmission time of the power amount request command and the reception time of the power amount response signal. The period determining unit 320 determines that the period of the master request command has been changed when the power amount response signal corresponding to the power amount request command is received in excess of a preset timer.

The new cycle calculating unit 330 calculates a new request command cycle by avoiding the master request command cycle. The new period calculating unit 330 calculates a new request command period by avoiding the changed master request command period when the period determining unit 320 determines that the master request command period has changed.

The new cycle calculating unit 330 checks the number of new request commands added (N (N is a natural number)). In order to minimize interference, the new period calculator 330 sets a time point divided by N+1 (N is a natural number) in the whole time unit as a new request command period. The new period calculator 330 transmits a new request command added to the slave measurement device 130 at each time point divided by N+1.

The new period calculating unit 330 sets an intermediate time point divided into 2 (N+1) of the whole time unit as a new request command period in order to minimize interference when the added new request command is one (N). The new period calculating unit 330 sets the time point of the third division (N+1) of the whole time unit as a new request instruction period to minimize interference when the added new request instruction is two (N), and the third division (N +1) Two (N) new request commands are transmitted each time.

The slave communication unit 340 generates a new request command different from the power amount request command. The slave communication unit 340 transmits a new request command to the slave measurement device 130 at a new request command period.

When the slave communication unit 340 confirms that the period of the master request command is changed based on the power amount request command and the power amount response signal from the period identification unit 320, the slave communication unit 340 transmits a new request command to the slave measurement device 130 in the new request command period. Stop operation.

When the slave communication unit 340 confirms that the master request command period has been changed by the period identification unit 320, when the changed master request command period and the new request command period partially overlap, the changed master request command period is preferentially processed.

The slave communication unit 340 transmits a new request command including at least one of a current request command, a voltage request command, a power factor request command, and a loss request command to the slave measurement device 130 at a new request command cycle.

The operator communication unit 350 receives and stores a new response signal corresponding to the new request command from the slave measurement device 130, and transmits the new response signal to the new operator device. The operator communication unit 350 processes the new response signal in a predetermined format and then transmits it to at least one device of a demand response market (DR), an energy management system (EMS), and a building energy management system (BEMS). .

3B is a block diagram illustrating in detail a line switching circuit according to the present embodiment.

The line switching circuit unit 210 according to this embodiment includes a sensing unit 362, a line switching unit 364, and a control unit 366. Components included in the line switching circuit unit 210 are not necessarily limited thereto.

The line switching part 364 includes a contact a, a contact b, and a contact c.

One side of the contact c is connected to the master collection device 110, and the other side of the contact c is transferred to the contact a or the contact b. One side of the contact b is switched to the contact a in abnormal operation, and the other side of the contact b becomes the contact b` to be connected to the slave measurement device 130. One side of the contact a is connected to the contact c during normal operation, and the other side of the contact a is connected to the master intercept unit 312.

The line switching part includes a contact a`, a contact b`, and a contact c`.

One side of the contact c` is transferred to the contact a` or the contact b`, and the other side of the contact c` is connected to the slave measurement device 130. One side of contact b` is connected to the other side of contact b, and the other side of contact b` is connected to contact c` in abnormal operation. One side of the contact a` is connected to the slave intercept unit 314, and the other side of the contact a` is connected to the contact c` in normal operation.

Each component included in the line switching circuit unit 210 may be connected to a communication path connecting a software module or a hardware module inside the device to operate organically with each other. These components communicate using one or more communication buses or signal lines.

Each component of the line switching circuit unit 210 shown in FIG. 3B refers to a unit that processes at least one function or operation, and may be implemented by a software module, a hardware module, or a combination of software and hardware.

The sensing unit 362 checks whether the operating voltage in the measurement information relay device 120 is normal.

The line switching unit 364 operates to switch the master collection device 110, the slave measurement device 130, and the communication line under control.

When the operating voltage is less than a preset threshold, the control unit 366 controls the line switching unit 364 to switch the communication line so that the master collection device 110 is directly connected to the slave measurement device 130.

The control unit 366 is connected to the local hardware interlock (Local Hardware Interlock), when the operating voltage cutoff, internal module malfunction, adapter failure, power failure, software error, etc. occurs, the master collection device 110 is a slave measurement device Switch the communication line so that it is directly connected to

When the operating voltage is greater than or equal to a preset threshold, the control unit 366 recognizes that the signal is a normal operation, so that the signal line of the contact c is transferred to the contact a, and the signal line of the contact c` is transferred to the contact a`.

When the operating voltage is less than a preset threshold, the controller 366 recognizes it as an abnormal operation so that the signal line of the contact c is transferred to the contact b, and the signal line of the contact c` is transferred to the contact b`.

4 is a flowchart for explaining a measurement information relay method according to the present embodiment.

The measurement information relay device 120, the master intercept unit 312 intercepts the electric power request command that the master collection device 110 transmits to the slave measuring device 130 on the line, and then transmits the electric power request command to the slave measuring device. Bypass to (130) (S410).

The measurement information relay device 120 intercepts the electric power response signal corresponding to the electric power request command that the slave measuring device 130 transmits to the master collecting device on the line and bypasses it to the master collecting device 110 (S420).

The measurement information relay device 120 determines the master request command period based on the transmission time of the power amount request command and the reception time of the power amount response signal (S430).

In step S430, the measurement information relay device 120 analyzes the periodicity of the master collection device 110 based on the transmission time of the power request command and the reception time of the power response signal, thereby measuring the slave device 130 in a time range without interference. Calculate a new request command cycle to communicate with.

The measurement information relay device 120 calculates a new request command cycle by avoiding the master request command cycle (S440).

In step S440, the measurement information relay device 120 checks the number of new request commands added (N (N is a natural number)). In order to minimize interference, the measurement information relay device 120 sets a time point divided by N+1 (N is a natural number) in the whole time unit as a new request command period. The measurement information relay device 120 transmits a new request command added to the slave measurement device 130 at each time point classified as N+1.

The measurement information relay device 120 generates a new request command different from the power request command, and a new request command (including at least one of a current request command, a voltage request command, a power factor request command, and a loss request command). Periodically, it transmits to the slave measurement device 130 (S450).

In step S450, when the measurement information relay device 120 determines that the master request command period is changed based on the power amount request command and the power amount response signal, the new request command cycle transmits a new request command to the slave measurement device 130 To stop.

If it is determined that the master request command period is changed, the measurement information relay device 120 preferentially processes the changed master request command period when the changed master request command period and the new request command period partially overlap.

The measurement information relay device 120 receives and stores a new response signal corresponding to the new request command from the slave measurement device 130, and transmits the new response signal to the new operator device (S460).

In step S460, the measurement information relay device 120 processes a new response signal into a preset format, and then processes at least one of a demand response market (DR), an energy management system (EMS), and a building energy management system (BEMS). Send to one or more devices.

Although FIG. 4 describes that steps S410 to S460 are sequentially executed, the present invention is not limited thereto. In other words, since the steps described in FIG. 4 may be changed and executed or one or more steps may be executed in parallel, FIG. 4 is not limited to the time series order.

As described above, the measurement information relay method according to the present embodiment described in FIG. 4 may be implemented as a program and recorded in a computer-readable recording medium. The program for implementing the measurement information relay method according to the present embodiment is recorded, and the computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored.

The above description is merely illustrative of the technical idea of the present embodiment, and those skilled in the art to which this embodiment belongs may be capable of various modifications and variations without departing from the essential characteristics of the present embodiment. Therefore, the present embodiments are not intended to limit the technical spirit of the present embodiment, but to explain, and the scope of the technical spirit of the present embodiment is not limited by these embodiments. The protection scope of the present embodiment should be interpreted by the claims below, and all technical spirits within the equivalent range should be interpreted as being included in the scope of the present embodiment.

110: master collection device 120: measurement information relay device
130: slave measuring device
210: line switching circuit unit 220: measurement information relay unit
312: master intercept section
314: slave intercept unit
320: cycle identification unit 330: new cycle calculation unit
340: slave communication unit 350: operator communication unit
362: detection unit 364: line transfer section
366: control

Claims (13)

A master intercept unit for intercepting a power amount request command transmitted from the master collection device to the slave measurement device on the line and bypassing the power amount request command to the slave measurement device;
A slave intercept unit for intercepting a power amount response signal corresponding to the power amount request command transmitted from the slave measurement device to the master collection device on a line and bypassing the power amount response signal to the master collection device;
A period identification unit for determining a master request command period based on a transmission time point of the power amount request command and a reception time point of the power amount response signal;
A new cycle calculating unit that calculates a new request command cycle by avoiding the master request command cycle;
A slave communication unit generating a new request command different from the power request command and transmitting the new request command to the slave measurement device at the new request command period; And
Including the operator communication unit for receiving a new response signal corresponding to the new request command from the slave measurement device to transmit to a new operator device,
When the period determining unit determines that the master request command period has been changed based on the power request command and the power response signal,
The slave communication unit stops the operation of transmitting the new request command to the slave measurement device at the new request command period. According to claim 1,
One side of the master intercept portion is connected to the output terminal of the master collection device, the other side of the master intercept portion is connected to the input terminal of the slave measuring device,
A measurement information relay device, characterized in that one side of the slave intercept part is connected to the input terminal of the master collection device, and the other side of the slave intercept part is connected to the output terminal of the slave measurement device. According to claim 1,
The cycle grasping unit,
Characterized in that it analyzes the periodicity of the master collection device based on the transmission time of the electric power request command and the reception time of the electric power response signal, and calculates the new request command period for further communication with the slave measurement device in a time range without interference. Measurement information relay device. delete According to claim 1,
When it is determined that the master request command period has been changed by the period detecting unit, the slave communication unit preferentially processes the changed master request command period when the changed master request command period and the new request command period partially overlap. Characteristic measurement information relay device. According to claim 1,
The new cycle calculation unit,
Measurement information relay device, characterized in that for calculating the new request command cycle to avoid the changed master request command cycle. According to claim 1,
The period grasping unit is a measurement information relay device, characterized in that when the power response signal corresponding to the power request command is received exceeds a preset timer, the master request command period is changed. According to claim 1,
The slave communication unit,
A measurement information relay device comprising transmitting the new request command including at least one of a current request command, a voltage request command, a power factor request command, and a loss request command to the slave measurement device at the new request command period. According to claim 1,
The operator communication unit,
Measurement characterized in that the new response signal is processed into a preset format and then transmitted to at least one device among a demand resource trading market (DR), an energy management system (EMS), and a building energy management system (BEMS). Information relay device. According to claim 1,
When the master collection device transmits a request command for a specific measurement unit among a plurality of measurement units within the power amount request command,
A measurement information relay device characterized in that all the measurement units included in the slave measurement device receive a request command for the specific measurement unit, but only the specific measurement unit among a plurality of measurement units transmits the power response signal in response to the request command. . The method of claim 10,
A sensing unit for confirming whether the operating voltage in the device is normally operated;
A line switching unit operable to switch the master collection device and the slave measurement device and a communication line under control; And
When the operating voltage is less than a preset threshold, a control unit that controls the line switching unit to switch the communication line so that the master collection device is directly connected to the slave measurement device
Measurement information relay device comprising a. The method of claim 11,
The control unit,
When any of the operation voltage cutoff, internal module malfunction, adapter failure, power failure, or software error occurs, the master collection device is directly connected to the slave measurement device by connecting with a local hardware interlock. Measurement information relay device, characterized in that for switching the communication line to be connected. A process of intercepting a power amount request command transmitted from the master collection device to the slave measurement device on the line and bypassing the power amount request command to the slave measurement device;
Intercepting a power amount response signal corresponding to the power amount request command transmitted from the slave measurement device to the master collection device on a line and bypassing it to the master collection device;
Determining a master request command period based on a transmission time of the power request command and a reception time of the power response signal;
Calculating a new request command cycle by avoiding the master request command cycle;
Generating a new request command different from the power request command and transmitting the new request command to the slave measurement device in the new request command period; And
And receiving a new response signal corresponding to the new request command from the slave measurement device and transmitting it to a new operator device.
When it is determined that the master request command period is changed based on the power request command and the power response signal, after the process of transmitting to the slave measurement device at the new request command period, the new request command is sent to the new request command period. Method for relaying measurement information, characterized in that it further comprises the step of stopping the operation to transmit to the slave measurement device.

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