KR102644688B1 - RTU with data storing function and server monitoring function - Google Patents

Abstract

In the present invention, the meter reading data is stored as backup data in the RTU before being transmitted to the meter integrated management server through the RTU, and at the same time, in this process, the RTU performs a monitoring function for the storage function and other functions of the meter integrated management server. This relates to an RTU with a data storage function and a server monitoring function. The RTU with a data storage function and a server monitoring function according to the present invention has a storage unit for storing meter reading data transmitted from the consumer's meter. Including, the meter reading data transmitted from the consumer's meter is stored in the storage unit and transmitted to the meter integrated management server, but before transmission of the meter reading data to the meter integrated management server, whether to initiate data transmission to the meter integrated management server is checked. After transmitting an inquiry signal, the meter reading data is transmitted according to a data transmission request signal from the meter integrated management server.

Description

RTU with data storing function and server monitoring function}

The present invention relates to an RTU with a data storage function and a server monitoring function. More specifically, the meter reading data is stored as backup data in the RTU before being transmitted to the meter integrated management server through the RTU. This is about RTU, which has a data storage function and a server monitoring function that allows the RTU to exercise a monitoring function for the storage function and other functions of the meter integrated management server in the process.

In general, meters are installed in each home, factory, or office building to display the amount of electricity, water, gas, hot water, and heating used.

In addition, the traditional meter reading method has been widely used in the past and even to this day, in which a meter reader visits the consumer (each household, office, etc.) subject to meter reading and performs the meter reading directly.

However, in the case of this traditional meter reading method, the meter reading takes a lot of time because the meter reader must personally visit many consumers each day, meter reading is impossible when the consumer is absent, and meter reading costs a lot because many meter readers are needed, etc. It is causing various difficulties. In addition, there is always a possibility that the meter may be recorded or entered incorrectly during the meter reading process, and this could result in an error in which an incorrect fee is charged.

For these reasons, research is currently being actively conducted on methods to accurately measure usage using meter reading devices, and in collecting meter reading information, the so-called digital meter linkage method, which receives meter reading directly as digital data from the meter, has recently been adopted. It accounts for a large portion of the remote meter reading field.

In other words, a remote meter reading system is being developed in which a remote meter reading terminal receives meter reading data and transmits it to a management server.

However, when meter reading data from each consumer is simultaneously transmitted to the management server in an area with a poor communication environment, such as an area with a high concentration of consumers, various abnormalities such as data collisions and overload of the management server occur, preventing normal transmission of meter reading data. It may not be possible.

In addition, problems with the data storage function that may occur in the management server may make it impossible to transmit any more data from the remote meter reading terminal, or transmission may not be possible for a certain period of time due to transmission failure due to disconnection of the transmission line or external electromagnetic induction. It can happen.

In addition, in remote meter reading systems that require continuous metering, information may be missing in some sections due to the above-mentioned phenomena, which may cause confusion in identifying and analyzing trends in metering information.

In addition to the above-mentioned difficulties, the existing remote meter reading system may cause data to be damaged or lost in the database server of the management server even if data is transmitted normally from the remote meter reading terminal.

Meanwhile, RTU (Remote Terminal Unit) is a device that combines with a sensor and transmits sensor data generated from the sensor to a server. And the sensors combined with these RTUs may be diverse, such as analog sensors that generate analog sensor signals or digital sensors that generate digital signals.

That is, the remote meter reading terminal of the remote meter reading system corresponds to a type of RTU, and therefore, the remote meter reading terminal of the remote meter reading system will be referred to as RTU in the following description.

Korean Patent No. 10-0446427 (announced on September 1, 2004), “Remote meter reading device installed between the host computer and the metering device to easily transmit meter reading information” Korean Patent Publication No. 10-2008-0000718 (published on January 3, 2008), “Meter reading data management device and method”

In an embodiment of the present invention, between the process of transmitting meter reading data to the meter integrated management server through the RTU and using it for storage, management, and billing, the meter reading data transmitted to the meter integrated management server is also stored as backup data in the RTU. As a result, if the meter reading data is not stored properly due to an error in the meter integrated management server and its database server, the corresponding inspection data is provided from the RTU to the meter integrated management server and its database server, so that data recovery can be achieved. As a result, RTU, which has a data storage function and a server monitoring function, is provided to compensate for the omission of metering information and ensure that trends and analysis of future billing and metering information are always accurately performed.

In addition, in an embodiment of the present invention, between the process of transmitting the meter reading data to the meter integrated management server through the RTU, the RTU inquires with the meter integrated management server whether transmission of the meter reading data is initiated, and after going through the approval process, the meter reading data is sent to the meter integrated management server. As the transmission progresses, it is frequently checked whether there are any abnormalities in the storage function or other functions of the meter integrated management server, and when an abnormality occurs, the fact is immediately notified to the integrated situation room manager of the meter integrated management server so that action can be taken. As a result, RTU, which has a data storage function and server monitoring function, is provided to ensure that the meter information is always transmitted, managed, and used normally to the meter integrated management server.

RTU, which has a data storage function and a server monitoring function according to an embodiment of the present invention, receives meter reading data (hereinafter “meter reading data”) from the consumer's meter and integrates meter management and billing functions. An RTU (Remote Terminal Unit, 300) that transmits to a management server, includes a storage unit for storing the meter reading data transmitted from the meter, stores the meter reading data transmitted from the meter in the storage unit, and integrates the meter reading data. Transmitted to the management server, but before transmitting the meter reading data to the meter integrated management server, a signal (hereinafter referred to as “data transmission confirmation signal”) to inquire whether data transmission is initiated to the meter integrated management server is sent to confirm the data transmission. As a data transmission request signal from the meter integrated management server for the signal is received, the meter reading data may be transmitted to the meter integrated management server.

In addition, the RTU, which has a data storage function and a server monitoring function according to an embodiment of the present invention, includes a first communication module that receives the inspection data from the meter, and the inspection data received from the first communication module. At the same time as storing in the storage unit, temporarily storing it in memory, transmitting the data transmission confirmation signal to the meter integrated management server, and then receiving the data transmission request signal from the meter integrated management server, the inspection data in the memory It may include a control module that outputs and a second communication module that transmits the inspection data output from the control module to the meter integrated management server.

In addition, if the data transmission request signal is not received from the meter integrated management server within a preset time after transmitting the data transmission confirmation signal to the meter integrated management server, the control module sends the data transmission confirmation signal to the meter integrated management server. It may include a function to transmit a signal requesting server inspection to the administrator of the server.

According to an embodiment of the present invention, during the process in which the meter reading data is transmitted to the meter integrated management server through the RTU and used for storage, management, and billing, the meter reading data transmitted to the meter integrated management server is also backup data to the RTU. If the meter reading data is not stored properly due to an error in the meter integrated management server and its database server, the corresponding inspection data is provided from the RTU to the meter integrated management server and its database server, so that data recovery can be done. As a result, the omission of metering information is compensated, allowing future trends in billing and metering information to be identified and analyzed accurately at all times.

In addition, during the process of transmitting the meter reading data to the meter integrated management server through the RTU, the RTU inquires with the meter integrated management server whether to start transmitting the meter reading data, and after going through the approval process, the meter reading data is transmitted. , it is checked at any time whether there is an error in the storage function or other functions of the meter integrated management server, and when an abnormality occurs, the fact is immediately notified to the manager of the integrated situation room of the meter integrated management server so that action can be taken, so that the meter's weighing information is It can always be transmitted, managed and used normally on the meter integrated management server.

1 is a block diagram illustrating an RTU with a data storage function and a server monitoring function according to an embodiment of the present invention.
Figure 2 is a diagram illustrating an example in which some components are added to an RTU with a data storage function and a server monitoring function according to an embodiment of the present invention.
Figure 3 is a block diagram illustrating the electrical configuration of the additional configuration according to Figure 2

The following detailed description of the present invention is an embodiment in which the present invention can be practiced and refers to the accompanying drawings, which are shown as examples of the corresponding embodiments. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the invention are different from one another but are not necessarily mutually exclusive. For example, specific shapes, structures and characteristics described herein may be implemented in one embodiment without departing from the spirit and scope of the invention. Additionally, it should be understood that the location or arrangement of individual components within each described embodiment may be changed without departing from the spirit and scope of the invention.

Accordingly, the detailed description set forth below is not intended to be taken in a limiting sense, and the scope of the invention is limited only by the appended claims together with all equivalents to what those claims would assert if properly described. Similar reference numbers in the drawings refer to identical or similar functions across various aspects.

The terms used in the present invention are general terms that are currently widely used as much as possible while considering the function in the present invention, but this may vary depending on the intention or precedent of a person working in the art, the emergence of new technology, etc. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the relevant invention. Therefore, the terms used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than simply the name of the term.

When it is said that a certain part of the whole of an invention “includes” a certain component, this means that, unless specifically stated to the contrary, it does not exclude other components but may further include other components. In addition, “…” stated in the specification. wealth", "… Terms such as “module” refer to a unit that processes at least one function or operation, which may be implemented as hardware or software, or as a combination of hardware and software.

With reference to FIGS. 1 to 3 , an RTU having a data storage function and a server monitoring function according to an embodiment of the present invention will be described.

Figure 1 is a block diagram illustrating an RTU with a data storage function and a server monitoring function according to an embodiment of the present invention.

As shown, the RTU, which has a data storage function and a server monitoring function according to an embodiment of the present invention, receives meter reading data (hereinafter “meter reading data”) from the consumer's meter 100 and This is an RTU (Remote Terminal Unit, 300) that transmits the management and billing functions for (100) to the meter integrated management server (200).

And this RTU (300) includes a storage unit 310 for storing meter reading data transmitted from the meter 100, and stores the meter reading data transmitted from the meter 100 in the storage unit 310 and manages the meter integrated management. Transmitted to the server 200, however, before transmitting the meter reading data to the meter integrated management server 200, a signal (hereinafter referred to as “data transmission confirmation signal”) is sent to the meter integrated management server 200 to inquire whether to initiate data transmission. After transmission, as the data transmission request signal from the meter integrated management server 200 in response to the data transmission confirmation signal is received, the meter reading data is transmitted to the meter integrated management server 200.

Additionally, the RTU 300 may be configured to include a first communication module 320, a control module 330, and a second communication module 340 in addition to the storage unit 310 described above.

The first communication module 320 performs the function of receiving the inspection data from the meter 100.

The control module 330 stores the inspection data received from the first communication module 320 in the storage unit 310 and temporarily stores it in the memory 350, and then sends the data transmission confirmation signal to the meter integrated management server ( 200), the inspection data in the memory 350 is output as the data transmission request signal is received from the meter integrated management server 200.

The second communication module 340 performs the function of transmitting the inspection data output from the control module 330 to the meter integrated management server 200.

In addition, the control module 330 transmits the data transmission confirmation signal to the meter integrated management server 200, and if the data transmission request signal is not received from the meter integrated management server 200 within a preset time, the control module 330 manages the meter integrated management server 200. It may include a function of transmitting a signal requesting server inspection to the manager of the integrated situation room where the server 200 is installed.

According to the above-mentioned configuration, during the process of transmitting the meter reading data to the meter integrated management server through the RTU and using it for storage, management, and billing, the meter reading data transmitted to the meter integrated management server is also stored as backup data in the RTU. As a result, if the meter reading data is not stored properly due to an error in the meter integrated management server and its database server, the corresponding inspection data is provided from the RTU to the meter integrated management server and its database server, so that data recovery can be achieved. There will be. And this complements the phenomenon of omission of metering information, thereby ensuring that future trends in billing and metering information and analysis are always carried out accurately.

In addition, during the process of transmitting the meter reading data to the meter integrated management server through the RTU, the RTU inquires with the meter integrated management server whether to start transmitting the meter reading data, and after going through the approval process, the meter reading data is transmitted. , it is checked at any time whether there is an abnormality in the storage function or other functions of the meter integrated management server, and when an abnormality occurs, the fact is immediately notified to the integrated situation room manager of the meter integrated management server so that action can be taken. In other words, the RTU can perform the monitoring function for the storage function and other functions of the meter integrated management server, which results in the meter's metering information being always normally transmitted, managed, and used by the meter integrated management server.

Next, with reference to FIGS. 2 and 3, an example in which some configurations are added to the RTU having a data storage function and a server monitoring function according to an embodiment of the present invention will be described.

FIG. 2 is a diagram illustrating an example in which some components are added to an RTU with a data storage function and a server monitoring function according to an embodiment of the present invention, and FIG. 3 is an electrical configuration of the additional components according to FIG. 2. This is a block diagram illustrating.

As shown, the storage unit 310 consists of an external storage unit detachably coupled to the RTU (300).

In addition, in the RTU (300), a pair of RTU main connectors (360) for connecting the storage units (310) are in a state where one side is exposed to the outside from the housing (370) of the RTU (hereinafter “RTU housing”), and at the same time, they are aligned vertically. It is installed as a built-in type in the RTU housing 370, arranged in a row along the line.

And the RTU (300) may be configured to further include a storage shelf module 381, a connection guide plate 382, and a solenoid actuator 383.

When the storage shelf module 381 is coupled to the RTU housing 370, the storage unit 310 is connected so that its connector 311 (hereinafter “storage connector”) faces the RTU main connector 360 of the RTU 300. It is arranged in a two-layer structure so that the storage unit 310 of each pair of RTU main body connectors 360 can be arranged to face the storage connector 311, so that the storage units 310 are arranged on a layer-by-layer basis. is located. And this storage shelf module 381 is detachably coupled to the RTU housing 370. At this time, the storage shelf module 381 can be detachably coupled to the RTU housing 370 in various forms through known techniques. As it can be implemented, detailed description thereof is omitted in this embodiment and is briefly shown in the form of a box in the drawings.

The connection guide plate 382 is installed in each layer of the storage shelf module 381, and each of these connection guide plates 382 is oriented either in a direction approaching the RTU main body connector 360 or in a direction away from the RTU main body connector 360. It is coupled to the storage shelf module 381 in a form that slides along the structure and has a structure that allows the storage unit 310 to be fixedly mounted on the upper surface.

The solenoid actuator 383 connects the storage unit 310, which is fixedly mounted on the upper surface of the connection guide plate 382, to the storage unit connector 311 to the RTU main body connector 360. ) is installed to provide sliding power to the connection guide plate 382.

And the control module 330 connects one of the two storage units 310 installed on each floor to the storage shelf module 381 by connecting its storage connector 311 to the RTU main body connector 360. When connected, the other storage unit 310 controls the operation of the solenoid actuator 383 to maintain the storage unit connector 311 in a waiting state for connection to the RTU main body connector 360.

That is, when the storage unit 310 currently connected to the RTU main connector 360 fills all of its storage capacity, the control module 330 releases the connection and simultaneously connects the storage unit 310 to the storage connector of another storage unit 310. (311) controls the operation of the solenoid actuators (383) so that they are connected to another RTU main body connector (360) of the RTU (300).

Here, control signal transmission and reception between the control module 330 and the solenoid actuator 383 may be performed through short-distance wireless communication modules 391 and 392.

In addition, when the storage unit 310 currently connected to the RTU main connector 360 fills all of its storage capacity, the control module 330 requests replacement of the storage unit 310 or movement and deletion of stored data. A signal is transmitted to the meter integrated management server (200) so that the manager of the integrated situation room where the meter integrated management server (200) is installed can recognize the fact, or a smart mobile device carried by the manager in charge of the relevant RTU (300) You can send it to (400) so that the manager in charge is aware of the fact.

According to the above-described configuration, the storage unit that performs the backup function of the meter reading data that is read from the meter and then transmitted to the meter integrated management server through the RTU is composed of a detachable external configuration for the RTU and is provided as a pair to As it performs sequential access and storage functions, when one storage unit fills its storage capacity, the other storage unit immediately performs a data backup function by storing the meter reading data. Accordingly, the RTU's meter reading data backup work can proceed continuously without interruption.

To explain further, when one storage unit fills all of its storage capacity, the fact is immediately notified to the manager of the integrated situation room or the manager in charge of the relevant RTU, so that the storage unit can be replaced or the data in the relevant storage unit can be moved to another storage device. At the same time, since deleting the data in the relevant storage unit can be done immediately, the meter reading data backup operation through the RTU storage unit can proceed continuously and stably without interruption.

As described above, in this description, specific details such as specific components and limited embodiments and drawings have been described, but this is only provided to facilitate a more general understanding of the present invention, and the present invention is not limited to the above embodiments. No, those of ordinary skill in the field to which the present invention pertains can make various modifications and variations from this description.

Therefore, the idea of the present invention should not be limited to the described embodiments, and the claims described below as well as all modifications that are equivalent or equivalent to the claims will be said to fall within the scope of the idea of the present invention.

100: meter 200: meter integrated management server
300: RTU 310: Storage unit
311: storage connector 320: first communication module
330: Control module 340: Second communication module
350: Memory 360: RTU main body connector
370: RTU housing 381: Storage shelf module
382: Connection guide plate 383: Solenoid actuator
391,392: Short-distance wireless communication module 400: Smart mobile device

Claims (2)

A Remote Terminal Unit (RTU) that receives meter reading data (hereinafter “meter reading data”) from the consumer’s meter 100 and transmits it to the meter integrated management server 200, which has management and billing functions for the meter 100. 300),
Including a storage unit 310 for storing the meter reading data transmitted from the meter 100, the meter reading data transmitted from the meter 100 is stored in the storage unit 310 and the meter integrated management server 200. However, before transmitting the meter reading data to the meter integrated management server 200, a signal (hereinafter referred to as “data transmission confirmation signal”) is sent to the meter integrated management server 200 to inquire whether to start data transmission. When a data transmission request signal from the meter integrated management server 200 in response to the data transmission confirmation signal is received, the meter reading data is transmitted to the meter integrated management server 200,
A first communication module 320 that receives the inspection data from the meter 100;
The inspection data received from the first communication module 320 is stored in the storage unit 310 and temporarily stored in the memory 350, and then the data transmission confirmation signal is sent to the meter integrated management server 200. A control module 330 that outputs the inspection data of the memory 350 as the data transmission request signal is received from the meter integrated management server 200 after transmission; and
It includes a second communication module 340 that transmits the inspection data output from the control module 330 to the meter integrated management server 200,
If the data transmission request signal is not received from the meter integrated management server 200 within a preset time after transmitting the data transmission confirmation signal to the meter integrated management server 200, the control module 330 integrates the meter. It includes a function to transmit a signal requesting server inspection to the manager of the integrated situation room where the management server 200 is installed,
The storage unit 310 consists of an external storage unit detachably coupled to the RTU (300),
In the RTU (300), a pair of RTU main connectors (360) for connecting the storage units (310) are exposed to the outside from the housing (370 (hereinafter “RTU housing”)) of the RTU (300). At the same time, it is installed in the RTU housing 370 as a built-in type, arranged in a row along the vertical direction,
The RTU (300),
When coupled to the RTU housing 370, the storage unit 310 is arranged so that its connector 311 (hereinafter “storage connector”) faces the RTU main body connector 360 of the RTU 300. However, the storage unit 310 is arranged in a two-layer structure so that the storage unit 310 of each pair of RTU main connectors 360 can be arranged to face the storage unit connector 311, so that the storage unit 310 is located by layer, A storage shelf module 381 detachably coupled to the RTU housing 370;
The storage shelf module 381 is installed in each layer, and each storage shelf module slides in a direction approaching the RTU main body connector 360 or in a direction away from the RTU main body connector 360. A connection guide plate 382 that is coupled to 381 and has a structure that allows the storage unit 310 to be fixedly mounted on the upper surface;
The storage unit 310 fixedly mounted on the upper surface of the connection guide plate 382 is installed on the storage unit shelf module 381 so that the storage unit connector 311 is connected to the RTU main body connector 360. It includes a solenoid actuator 383 that provides sliding power to the connection guide plate 382,
When the storage unit 310 currently connected to the RTU main connector 360 fills all of its storage capacity, the control module 330 disconnects the storage unit 310 and simultaneously connects the storage unit 310 to another storage unit. Control the operation of the solenoid actuators 383 so that the storage connector 311 of the RTU 300 is connected to the other RTU main body connector 360 of the RTU 300, and control the operation of the storage unit 310 with all storage capacity. A signal requesting replacement or movement or deletion of stored data is transmitted to the meter integrated management server 200 so that the manager of the integrated situation room where the meter integrated management server 200 is installed can recognize the fact, or the corresponding RTU An RTU with a data storage function and a server monitoring function, which is transmitted to the smart mobile device (400) carried by the manager in charge of (300) so that the manager in charge can recognize the fact.
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