KR20230023451A - Data concentration unit and automacic reset method for it and automacic reset device - Google Patents

Abstract

According to the present invention, an automatic reset device can comprise: a micro controller counting continuous relay failures for a request for reading from a reading server of a data concentration device to a power meter, and counting continuous relay failures for a reading response from the power meter to the reading server, and determining that there is a disorder in the data transmission/reception status when the counted continuous relay failures for the request for reading reaches a certain number or the counted continuous relay failures for a reading response reaches a certain number; and a power switching unit resetting the data concentration device when it is determined that there is a disorder in the data transmission/reception status. Therefore, the total number of disorders can be reduced.

Description

Automatic reset device, data concentrator and automatic reset method thereof

The present invention relates to an automatic reset device, a data concentrator, and an automatic reset method for the same that can eliminate holding of a data concentrator as a main component in an intelligent watt-hour meter system.

The Data Concentrator (DCU) installed in the construction of the AMI (Advanced Metering Infrastructure) infrastructure has a software watchdog function when holding the device, so if an error occurs in the device, it can be restored with a reset operation. However, when software self-holding occurs, remote reset operation is not possible. However, when examining actual DCU (Data Concentration Unit)-related failure cases, the number of failures due to holding of the data concentrator accounts for more than 40% of the maximum.

The main components of the data concentrator are composed of a power supply unit, a main board, and a modem for trunk network. The frequency of holding of the main board and modem is high. there is.

If holding occurs in a number of DCUs with limited personnel, and when the role of the data concentrator (function to acquire and transmit/receive data) cannot be performed, considerable recovery time is required, which may affect the meter reading success rate. can Therefore, a countermeasure for holding recovery of the data concentrator is required.

Republic of Korea Registration No. 10-0974345

An object of the present invention is to provide an automatic resetting device, a data concentrating device, and an automatic resetting method for the automatic resetting device capable of effectively eliminating the holding of the data concentrating device by itself.

An automatic reset device according to an aspect of the present invention counts successive relay failures in response to an inspection request from a meter reading server of a data concentrator to a power meter, and continuously relays failures in response to meter reading responses from the power meter to the meter reading server. a microcontroller that counts, but determines that the data transmission/reception state is abnormal when the count of consecutive relay failures for the meter reading request reaches a predetermined number or when the count of consecutive relay failures for the meter reading response reaches a predetermined number; and a power switching unit resetting the data concentrator when it is determined that the data transmission/reception state is abnormal.

Here, the microcontroller may have a built-in storage space or a storage space for counting successive relay failures for the meter reading request or the meter reading response in a built-in storage space or register.

Here, the power switching unit may perform a reset operation on the data concentrator by shutting off the power unit of the data concentrator for a predetermined period of time and then restoring it again.

A data concentrator according to another aspect of the present invention includes a communication module for performing data communication with one or more watt-hour meters and data communication with a meter reading server; a main board relaying the meter reading request of the meter reading server to the corresponding watt-hour meter and relaying the meter reading response from the corresponding watt-hour meter to the meter reading server; a power supply unit supplying driving power to the communication module and the main board; and counting continuous relay failures in response to meter reading requests from the meter reading server to the watt-hour meter, and counting continuous relay failures in response to meter reading responses from the watt-hour meter to the meter reading server, but successive relay failures in response to the meter reading requests. may include an automatic reset device that cuts off and restores the power unit for a predetermined period of time when the count reaches a predetermined number or when the count of continuous relay failures for the meter reading response reaches a predetermined number.

Here, the communication module includes a PLC modem as means for performing data communication with a plurality of watt-hour meters; and a backbone network communication modem as means for performing data communication with the inspection server.

Here, the automatic reset device may include a separate additional power source independently of the power supply unit.

Here, the automatic reset device may be connected to Ethernet or RS-232C of the data concentrator and monitor data between the data concentrator and the modem.

Here, the automatic reset device is installed at the front end of the primary circuit breaker for the power supply unit and is composed of a relay having a short-circuit contact and an open-state contact, and maintains a short-circuit contact when the data concentrator is in normal operation, It may include a power unit Off/On switch that maintains the contact in an open state for a certain period of time when an abnormality in data transmission/reception occurs.

An automatic reset method for a data concentrator according to another aspect of the present invention includes monitoring a communication relay process between a watt-hour meter and a meter reading server of the data concentrator; counting successive relay failures in response to meter reading requests from the meter reading server to the watt-hour meter, and counting successive relay failures in response to meter reading responses from the watt-hour meter to the meter reading server; and resetting the data concentrator when a count of consecutive relay failures for the meter reading request reaches a predetermined number or when a count of consecutive relay failures for the meter reading response reaches a predetermined number. .

Here, the process of counting successive relay failures for the meter reading request may include confirming receipt of the meter reading request from the meter reading server to the corresponding watt-hour meter; checking whether the meter reading request has been transmitted to the corresponding watt-hour meter during a predetermined relay processing time; increasing a first error count when the meter reading request is not transmitted to the corresponding watt-hour meter for a predetermined relay processing time; and checking whether the first error count reaches a predetermined number.

Here, the process of counting successive relay failures for the meter reading response may include: confirming receipt of the meter reading response from the watt-hour meter to the meter reading server; checking whether the inspection response is transmitted to the inspection server during a predetermined relay processing time; increasing a second error count when the inspection response is not transmitted to the inspection server for a predetermined relay processing time; and checking whether the second error count reaches a predetermined number.

Here, the resetting of the data concentrator may include: determining an error in the data transmission/reception state; restoring the power unit of the data concentrator after shutting it down for a predetermined period of time; and restoring the normal function of the data concentrator by resetting.

If the automatic reset device and / or automatic reset method according to the spirit of the present invention having the above configuration is implemented, there is an advantage in that the holding of the data concentrator, which is an obstacle to the intelligent watt-hour meter system, can be automatically and effectively resolved.

The automatic reset device and/or the automatic reset method of the present invention can initialize hardware and software through automatic reset when the AMI data concentrator is held, and has an advantage of reducing the total number of failures.

The automatic reset device and/or the automatic reset method of the present invention has the advantage of minimizing on-site visit measures, minimizing failure duration of up to 10 days or more in the past, and contributing to the improvement of the meter reading success rate and the reliability of facility operation.

1 is a block diagram illustrating one embodiment of an AMI data concentrator with an automatic reset device in accordance with the teachings of the present invention;
2 is a conceptual diagram illustrating a data relaying and meter reading monitoring process between a meter reading server and a watt-hour meter according to the spirit of the present invention;
3 is a flow diagram illustrating one embodiment of an automatic reset method for a data concentrator according to the teachings of the present invention;
4 is a flowchart illustrating a detailed process of determining a data transmission/reception state in the automatic reset method of FIG. 3;

In describing the present invention, terms such as first and second may be used to describe various components, but the components may not be limited by the terms. Terms are only for the purpose of distinguishing one element from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention.

When a component is referred to as being connected or connected to another component, it may be directly connected or connected to the other component, but it may be understood that another component may exist in the middle. .

Terms used in this specification are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions may include plural expressions unless the context clearly dictates otherwise.

In this specification, the terms include or include are intended to designate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features or numbers, It can be understood that the presence or addition of steps, operations, components, parts, or combinations thereof is not precluded.

In addition, shapes and sizes of elements in the drawings may be exaggerated for clearer description.

In the present invention, an automatic reset device is additionally installed in the AMI data concentrator in operation, and when software holding occurs in the data concentrator, the automatic reset device recognizes the holding and implements a function of restoring to a normal state through automatic reset do.

For example, the automatic reset device is installed inside a data concentrator using a wired/wireless trunk network. More specifically, the automatic reset device is connected to the Ethernet or RS-232C of the data concentrator, monitors data between the data concentrator and the modem, and detects a data transmission/reception error state when an error occurs in the transmission/reception state, A function of automatically resetting a power unit inside the data concentrator may be performed.

1 is a block diagram illustrating one embodiment of an AMI data concentrator with an automatic reset device according to the spirit of the present invention.

2 is a conceptual diagram illustrating a process of relaying data and monitoring a meter reading between a meter reading server and a watt-hour meter according to the spirit of the present invention.

The illustrated data concentrator 100 includes a communication module 120 that performs data communication with one or more watt-hour meters 10 and data communication with the meter reading server 40; Main board 140 relaying the meter reading request of the meter reading server 40 to the corresponding watt-hour meter 10 and relaying the meter reading response from the corresponding watt-hour meter 10 to the meter reading server 40; a power supply unit 160 supplying driving power to the communication module 120 and the main board 140; and counting continuous relay failures for the meter reading request from the meter reading server 40 to the watt-hour meter 10, and counting continuous relay failures for the meter reading response from the watt-hour meter 10 to the meter reading server 40; , When the count of consecutive relay failures for the meter reading request reaches a predetermined number or the count of continuous relay failures for the meter reading response reaches a predetermined number, the power supply unit 160 is automatically cut off and restored for a predetermined time. A reset device 200 is included.

For example, in a domestic environment, the communication module includes a PLC modem as a means for performing data communication with a plurality of watt-hour meters including the corresponding watt-hour meter 10, and as a means for performing data communication with the meter reading server 40. A backbone network communication modem may be provided. As the backbone network, for example, an optical communication network, HFC, LTE, 5G, D-TRS, etc. may be applied.

Since the automatic reset device 200 turns on/off the power supply unit 160 that supplies the entire power of the AMI data collection device, rather than receiving driving power from the power supply unit 160, it is independent of the power supply unit 160. It is desirable to have a separate additional power source (eg, battery, solar cell, etc.).

Since the main board 140 is substantially the same as that of a general AMI data collection device, a description thereof will be omitted.

The automatic reset device 200 counts successive relay failures in response to a request for meter reading from the meter reading server 40 of the data concentrator 100 to the watt-hour meter 10, and Count continuous relay failures for the meter reading response to the meter reading server 40, but the count of consecutive relay failures for the meter reading request reaches a predetermined number or the count of continuous relay failures for the meter reading response is a predetermined number When it reaches , the microcontroller 240 determines that the data transmission/reception state is abnormal; and a power switching unit 260 resetting the data concentrator when it is determined that the data transmission/reception state is abnormal.

The automatic reset device 200 shown in FIG. 1 is composed of a microcontroller 240 and a power supply off/on switch serving as a power switching unit 260.

A storage space for counting successive relay failures for the meter reading request (response) may be provided separately, but it is advantageous to secure a storage space built in the microcontroller 240 or a register for convenience.

Although not shown, the automatic reset device 200 includes a separate power source for supplying driving power of the automatic reset device itself to a primary battery, a secondary battery, a solar cell module, and the like; And it may further include a set value (time, number of times, etc.) storage unit for storing set values in an automatic reset process according to the spirit of the present invention. For example, with the set values, a predetermined number of criteria for determining continuous relay failures for the meter reading request as an error in the data transmission/reception state and a criterion for determining continuous relay failures for the meter reading response as an error in the data transmission/reception state are It may be a predetermined number, a time from receipt of the meter reading request or meter reading response, which is a criterion for determining each relay failure, to transmission, and the like.

The illustrated microcontroller 240 may perform real-time monitoring and analysis of transmitted/received data of the data collection device and control the off/on switch of the power unit when transmission/reception is impossible during a certain period.

For example, the microcontroller 240 may monitor (confirm) the data transmission/reception state by utilizing the Ethernet or RS-232C port of the main mode 140 of the data collection device.

The power unit Off/On switch can reset the data concentrator 100 by shutting off the internal power unit 160 of the data concentrator 100 for a certain period of time and then restoring it.

More specifically, the power unit Off/On switch is installed at the front end of the primary circuit breaker and is composed of a relay having a short-circuit contact and an open-state contact, and maintains a short-circuit contact when the data concentrator 100 is in normal operation. However, when an abnormality in data transmission/reception occurs (determined by the microcontroller 240), the power supply unit 160 may be turned Off/On by maintaining the contact in an open state for a certain period of time.

When the power supply of the power supply unit 160 is cut off through the automatic reset according to the above-described process, the main board 140 and the modem of the data concentrator can be hardware-reset. Thus, the function of the data collection device 100 is initialized. and can normalize holding disorders.

3 is a flowchart illustrating an embodiment of an automatic reset method for an AMI data concentrator that can be performed by an automatic reset apparatus according to the teachings of the present invention.

The illustrated automatic reset method for the data concentrator includes monitoring a communication relay process between the watt-hour meter and the meter reading server of the data concentrator (S20); counting successive relay failures for the meter reading request from the meter reading server to the watt-hour meter, and counting successive relay failures for the meter reading response from the watt-hour meter to the meter reading server (S40); and when a count of consecutive relay failures for the meter reading request reaches a predetermined number or when a count of consecutive relay failures for the meter reading response reaches a predetermined number, resetting the data concentrator (S60). can do.

In the illustrated flowchart, the step S40 described later in FIG. 4 is simply expressed as checking for an abnormality in transmission and reception data, and the step S60 determines an abnormality in the data transmission and reception state as a result of the execution of the step S40 in the microcontroller of the automatic reset device. Step (S62); Step of shutting off the power supply of the data concentrator for a certain period of time by using the power supply off/on switch and then restoring it again (S64); and restoring the normal function of the data concentrator by resetting (S66).

FIG. 4 is a flowchart illustrating a detailed process of determining a data transmission/reception state in step S40 of the automatic reset method of FIG. 3 .

In the illustrated flowchart, a communication state monitoring process based on a meter reading request and a communication status monitoring process based on a meter reading response are performed in parallel.

The process of monitoring the communication state based on the request for meter reading may include: confirming receipt of the meter reading request from the meter reading server to the corresponding watt-hour meter (S41); During a predetermined relay processing time, checking whether the meter reading request has been transmitted to the corresponding watt-hour meter (S42); increasing a first error count when the meter reading request is not transmitted to the corresponding watt-hour meter during a predetermined relay processing time (S43); and checking whether the first error count reaches a predetermined number (10 in the drawing) (S53), and accordingly determining that the data transmission/reception state is abnormal (S62).

The process of monitoring the communication state based on the meter reading response may include confirming receipt of the meter reading response from the watt-hour meter to the meter reading server (S46); checking whether the inspection response is transmitted to the inspection server during a predetermined relay processing time (S47); increasing a second error count if the inspection response is not transmitted to the inspection server during a predetermined relay processing time (S48); and checking whether the second error count reaches a predetermined number (10 in the drawing) (S58), and accordingly determining that the data transmission/reception state is abnormal (S62).

In the figure, if the meter reading request received in step S41 is transmitted to the corresponding watt-hour meter during the predetermined relay processing time, the first error count is reset to 0 (S51), and similarly during the predetermined relay processing time, When the meter reading request received in step S46 is transmitted to the corresponding watt-hour meter, the first error count is reset to 0 (S56).

The step of confirming receipt of the meter reading request (S41) and the step of confirming the receipt of the meter reading response (S46) may be performed sequentially or simultaneously, and the meter reading request or meter reading response is received in steps S41 and S46. When is confirmed, the communication status monitoring process based on the meter reading request or the communication status monitoring process based on the meter reading response described above is performed.

Next, a specific case of determining a data transmission/reception state by monitoring a meter reading request/response according to the flowchart of FIG. 4 and the conceptual diagram of FIG. 2 will be described.

In step ① of FIG. 2 , the meter reading server 40 requests the AMI data concentrator 100 to read the meter once every 15 minutes. Correspondingly, in process ②, the AMI data concentrator 100 requests a meter reading to the watt-hour meter (modem) in response to request ① (ie, transmits the meter reading request to the watt-hour meter corresponding to the meter reading request). The watt-hour meter (modem) transmits the meter reading value to the AMI data concentrator 100 in response to the meter reading request of number ②. The meter reading value transmitted at this time becomes the meter reading response to the meter reading request. In step ④, the AMI data concentrator 100 transmits the meter reading value (ie, meter reading response) transmitted in ③ to the meter reading server 40.

The microcontroller 200 debugs all transmitted and received data in the meter reading process through the console of the AMI data concentrator 100, and relays success/failure to the meter reading request or meter reading response according to the flowchart of FIG. 4 according to the spirit of the present invention. You can monitor whether 'data transmission/reception abnormality' occurs.

In the case of FIG. 4 , the microcontroller 200 determines that 'data transmission/reception abnormality occurs' when the following items occur continuously 10 or more times.

- When the meter reading request of number ② is not transmitted in relation to the meter reading request of number ①

- In the case of not transmitting the inspection response No. ④ for the inspection response No. ③

Next, the difference between the automatic reset function of the hardware method according to the idea of the present invention for the AMI data concentrator and the Watchdog function as a software holding theorem built into the AMI data concentrator will be examined.

The watchdog function means providing a function of automatically resetting software by determining when an abnormality occurs in a role of the data concentrator, such as an internal circuit.

The automatic reset device of the present invention monitors the transmission and reception data of the data concentrator in real time, determines that data is not transmitted several times or more, and performs a hardware reset. Therefore, the automatic reset method is different from the watchdog function .

In addition, since Watchdog performs its role in terms of software, it may not be able to perform its function in case the software itself holds or fails. function can be provided.

Those skilled in the art to which the present invention pertains should understand that the embodiments described above are illustrative in all respects and not limiting, since the present invention can be embodied in other specific forms without changing the technical spirit or essential characteristics thereof. only do The scope of the present invention is indicated by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts should be construed as being included in the scope of the present invention. .

10: power meter 40: meter reading server
100: data concentrator 120: communication module
140: main board 160: power unit
200: automatic reset device 240: microcontroller
260: power switching unit

Claims (12)

Counting continuous relay failures for meter reading requests from the meter reading server of the data concentrator to the watt-hour meter, counting continuous relay failures for meter reading responses from the watt-hour meter to the meter reading server, but continuously relaying the meter reading requests a microcontroller for determining that a data transmission/reception state is abnormal when a count of failures reaches a predetermined number or when a count of successive relay failures for the meter reading response reaches a predetermined number; and
If it is determined that the data transmission/reception state is abnormal, a power switching unit resetting the data concentrator.
An automatic reset device comprising a.
According to claim 1,
The microcontroller,
An automatic reset device having a built-in storage space or a storage space for counting successive relay failures for the meter reading request or the meter reading response in a register.
According to claim 1,
The power switch,
An automatic reset device for performing a reset operation on the data concentrator in a manner in which a power supply of the data concentrator is cut off for a predetermined period of time and then restored again.
a communication module performing data communication with one or more watt-hour meters and data communication with a meter reading server;
a main board relaying the meter reading request of the meter reading server to the corresponding watt-hour meter and relaying the meter reading response from the corresponding watt-hour meter to the meter reading server;
a power supply unit supplying driving power to the communication module and the main board; and
Counting continuous relay failures in response to meter reading requests from the meter reading server to the meter, and counting continuous relay failures in response to meter reading responses from the meter reading server to the meter reading request, An automatic reset device that cuts off and restores the power unit for a predetermined time when the count reaches a predetermined number or when the count of continuous relay failures for the meter reading response reaches a predetermined number
A data concentrator comprising a.
According to claim 4,
The communication module,
A PLC modem as means for performing data communication with a plurality of watt-hour meters; and
Backbone network communication modem as means for performing data communication with the inspection server
A data concentrator comprising a.
According to claim 4,
The automatic reset device,
A data concentrator having a separate additional power source independently of the power supply unit.
According to claim 4,
The automatic reset device,
A data concentrator connected to the data concentrator's Ethernet or RS-232C to monitor data between the data concentrator and the modem.
According to claim 4,
The automatic reset device,
Installed at the front end of the primary circuit breaker for the power supply unit, it is composed of a relay having a short-circuit contact point and an open-state contact point. When the data concentrator is in normal operation, the short-circuit contact point is maintained, and when an abnormality in data transmission/reception occurs, it is opened for a certain period of time. Power unit Off/On switch that maintains the status contact
A data concentrator comprising a.
monitoring a communication relay process between the watt-hour meter of the data concentrator and the meter reading server;
counting successive relay failures in response to meter reading requests from the meter reading server to the watt-hour meter, and counting successive relay failures in response to meter reading responses from the watt-hour meter to the meter reading server; and
resetting the data concentrator when a count of consecutive relay failures for the meter reading request reaches a predetermined number or when a count of consecutive relay failures for the meter reading response reaches a predetermined number;
An automatic reset method for a data concentrator comprising:
According to claim 9,
The process of counting successive relay failures for the meter reading request,
confirming receipt of a request for meter reading from the meter reading server to a corresponding watt-hour meter;
checking whether the meter reading request has been transmitted to the corresponding watt-hour meter during a predetermined relay processing time;
increasing a first error count when the meter reading request is not transmitted to the corresponding watt-hour meter for a predetermined relay processing time; and
Checking whether the first error count reaches a predetermined number
An automatic reset method for a data concentrator comprising:
According to claim 9,
The process of counting successive relay failures for the meter reading response,
confirming receipt of a meter reading response from the watt-hour meter to the meter reading server;
checking whether the inspection response is transmitted to the inspection server during a predetermined relay processing time;
increasing a second error count when the inspection response is not transmitted to the inspection server for a predetermined relay processing time; and
Checking whether the second error count reaches a predetermined number
An automatic reset method for a data concentrator comprising:
According to claim 9,
The step of resetting the data concentrator,
determining an error in the data transmission/reception state;
restoring the power unit of the data concentrator after shutting it down for a predetermined period of time; and
restoring normal functioning of the data concentrator by resetting;
An automatic reset method for a data concentrator comprising:

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