KR20190100077A - System for preventing maintenance and method using the same - Google Patents

Abstract

According to an embodiment of the present invention, a predictive maintenance system comprises: a plurality of production facilities provided on a production line; a plurality of programmable logic controllers (PLC) for controlling the production facilities, and detecting an alarm signal generated in the production facilities; a master PLC for determining a failure state of the production facilities from the alarm signal; an alarm server for converting the failure state of the production facilities detected by the master PLC into failure information to transmit the same or converting the failure information on the production facilities into an original QR code to transmit the same; and a personal portable terminal for outputting the failure state of the production facilities transmitted from the alarm server or outputting the original QR code.

Description

Predictive maintenance management system and predictive maintenance management method using the same {SYSTEM FOR PREVENTING MAINTENANCE AND METHOD USING THE SAME}

The present invention relates to a predictive maintenance management system and a predictive maintenance management method using the same, which is configured to wirelessly call an alarm occurring in a facility of a production line in real time and to transmit the alarm to a portable terminal, thereby providing a more effective and systematic alarm. A system that contributes to productivity improvement by predicting and preventing facility problems through the history and trend analysis of alarm history based on the construction of big data through the history management of alarms. It is about a method.

In recent years, as industrial facilities have been enlarged and advanced, productivity has been greatly improved and product quality has been improved.

However, if a failure occurs in each facility of the production line, the resulting economic loss is very large and there are many problems in terms of safety management.

In order to solve this problem, managers can efficiently recognize alarms generated at each facility of a production line, and there is an increasing demand for a management system that can efficiently manage facilities from alarms generated at each facility. .

In addition, the era of the 4th Industrial Revolution has begun in earnest, and research to build a differentiated smart factory is required by the introduction of systematic alarm transmission and predictive maintenance system.

Matters described in this Background section are intended to enhance the understanding of the background of the invention, and may include matters other than the prior art already known to those skilled in the art.

The present invention is to solve the problems as described above, to provide the administrator with the alarm signal generated from various production equipment installed in the production line efficiently, and to recognize the status of the facility to the manager through the analysis of the alarm signal generated It is an object of the present invention to provide a predictive maintenance management system and a predictive maintenance management method using the same.

In addition, another object of the present invention is to provide a predictive maintenance management system and a predictive maintenance management method using the same, which can prevent an alarm signal generated in a production facility from being deformed or damaged due to noise or hacking during transmission.

Prognosis maintenance management system according to an embodiment of the present invention for achieving the above object is a plurality of production facilities provided in the production line; A plurality of programmable logic controller (PLC) devices for controlling the plurality of production facilities and detecting alarm signals generated in the production facilities; A master PLC device that determines a failure state of the plurality of production facilities from the alarm signal; An alarm server for converting and transmitting a failure state of the production facility detected by the master PLC device into failure information or converting the failure information of the production facility into an original QR code (QR code); And a personal portable terminal outputting a failure state of the production facility transmitted from the alarm server or outputting the original QR code.

The alarm server generates the original QR code using the failure information of the production facility, transmits the original QR code to the personal portable terminal, and combines an arbitrary QR code and a decoding QR code to determine whether the original QR code is damaged. It can be generated and transmitted to the personal mobile terminal.

The alarm server divides the cells constituting the original QR code into even number of mini cells, assigns half of the even number of mini cells to one of two colors, and the other of the even number of mini cells. The random QR code may be generated by allocating one half of the mini cells to another color.

The alarm server divides the cells constituting the original QR code into even number of mini cells, assigns the cells corresponding to the mini cells assigned to one color to another color, and assigns the other color. The decoded QR cell may be generated by allocating the mini cell and the corresponding cell to the color.

The personal portable terminal may determine whether the original QR code is damaged by combining the arbitrary QR code transmitted from the alarm server and the decoding QR code.

The personal mobile terminal overlaps the original QR code partitioned by an even number of minicells and the decoding QR code partitioned by an even number of minicells, and if all the minicells are of any one color, the cell of the original QR code is the one. If some of the mini-cells of any one of the mini-cell is one of the color, it can be determined that the cell of the original QR code is the other index.

The failure information may include information regarding a location of a production line in which the production facility is installed, an order in which the production facility is installed, a location of a failure part in the production facility, and a failure type.

The alarm signal is composed of four digit alarm bits, the first digit indicates information about a production line in which the production facility is installed, the second digit indicates information about the order in which the production facility is installed, and the third digit indicates The information regarding the failure location of the production facility may be displayed, and the fourth digit may display information regarding the failure type.

The alarm server may convert a failure type corresponding to the failure type of the alarm signal into a voice signal and selectively transmit the converted voice signal to a plurality of radios for each predetermined group.

The apparatus may further include a radio connection repeater that is wirelessly connected to the alarm server and the plurality of radios to control a push-to-talk function of the plurality of radios.

When an alarm signal is generated in the production facility, the radio connection repeater may transmit a voice signal transmitted from the alarm server to a radio connected to a channel matching the channel registered in the alarm server.

The push-to-talk function of the transceiver may be activated at the time when an alarm signal is generated in the production facility, and the push-talk function may be terminated when the voice signal transmitted from the alarm server is terminated.

The alarm server displays the alarm signal generated in the production facility in real time, constructs the alarm signal as big data through history management, and generates the alarm signal in a daily / monthly / yearly table to generate the alarm signal. The history of the personal computer may be analyzed and transmitted to the personal mobile terminal.

Predictive maintenance management method according to another embodiment of the present invention, by the programmable logic controller (PLC) device, detecting the alarm signal generated in the production facility; Determining, by the master PLC device, a failure state of the production facility from the alarm signal; Converting, by an alarm server, the failure state of the production facility transmitted from the master PLC device into failure information or converting the failure information into an original QR code (QR code); And outputting, by the personal portable terminal, a failure state of the production facility transmitted from the alarm server or outputting the original QR code.

In the transmitting, the random QR code and the decoding QR code for determining whether the original QR code is damaged may be transmitted together.

The cells constituting the original QR code are divided into even numbered minicells, and half of the even numbered minicells are assigned to one of two colors, and the other half of the even numbered minicells. The random QR code may be generated by assigning to a different color to.

And dividing the cells constituting the original QR code into even numbered mini cells, allocating the cells corresponding to the mini cell assigned to one color to another color, and assigning the mini cell assigned to the other color. A corresponding QR code can be generated by assigning a corresponding cell to any of the above colors.

The method may further include determining, by the personal portable terminal, whether the original QR code is damaged by combining the arbitrary QR code transmitted from the alarm server and the decoding QR code.

If the original QR code partitioned by an even number of mini cells and the decoding QR code partitioned by an even number of mini cells overlap each other and all the mini cells are of any one color, the cell of the original QR code is determined to be the one index. When some of the mini cells are all one color, it may be determined that the original QR code cell is the other index.

The failure information may include information regarding a location of a production line in which the production facility is installed, an order in which the production facility is installed, a location of a failure part in the production facility, and a failure type.

The alarm signal is composed of four digit alarm bits, the first digit indicates information about a production line in which the production facility is installed, the second digit indicates information about the order in which the production facility is installed, and the third digit indicates The information regarding the failure location of the production facility may be displayed, and the fourth digit may display information regarding the failure type.

The method may further include converting, by the alarm server, a failure type of the alarm signal into a voice signal, and selectively transmitting the converted voice signal to a radio by a predetermined group.

An alarm generated by the alarm server to display the alarm signal generated in the production facility in real time, construct the alarm signal as big data through history management, and generate the alarm signal in a daily / monthly / yearly table The history of the signal may be analyzed and transmitted to the personal portable terminal.

According to the predictive maintenance management system and the predictive maintenance management method using the same according to the embodiment of the present invention as described above, by comparing the alarm signal generated in the production facility with the reference signal, it is possible to accurately determine the failure state of the production facility. Have

In addition, by transmitting a voice signal corresponding to the failure state of the production facility to the personal portable terminal, the administrator can quickly prepare a countermeasure according to the failure state of the production facility.

In addition, when the failure state of the production equipment is transmitted from the alarm server to the personal portable terminal as the original QR code, the arbitrary QR code and the decoding QR code are transmitted together, thereby determining whether the original QR code is damaged or not.

Since these drawings are for reference in describing exemplary embodiments of the present invention, the technical idea of the present invention should not be construed as being limited to the accompanying drawings.
1 is a conceptual diagram showing the configuration of a predictive maintenance management system according to an embodiment of the present invention.
2 is a view showing a breakdown, history and alarm trend analysis of the alarm signal provided by the predictive maintenance management system according to an embodiment of the present invention.
3 is a diagram showing an alarm setting method of the predictive maintenance management system according to an embodiment of the present invention.
4 is a diagram illustrating an alarm display in a personal portable terminal of a predictive maintenance management system according to an exemplary embodiment of the present invention.
5 is a diagram illustrating an original QR code according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating a state in which one cell constituting the original QR code is divided into four mini cells according to an embodiment of the present invention.
7 and 8 are diagrams for describing a method for generating an arbitrary QR code and a decoding QR code according to an embodiment of the present invention.
9 is a flowchart illustrating a predictive maintenance management method according to an embodiment of the present invention.

DETAILED DESCRIPTION Embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and like reference numerals designate like elements throughout the specification.

In addition, since the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of description, the present invention is not necessarily limited to those shown in the drawings, and is shown by enlarging the thickness in order to clearly express various parts and regions. It was.

In addition, some methods may be executed by at least one controller.

The term controller refers to a hardware device that includes a memory and a processor configured to execute one or more steps that are interpreted as an algorithmic structure.

The memory is configured to store algorithm steps, and the processor is specifically configured to execute the algorithm steps to perform one or more processes described below.

Further, the control logic of the present invention may be embodied as non-transitory computer readable media on computer readable means including executable program instructions executed by a processor, controller, or the like.

Examples of computer-readable means include, but are not limited to, ROM, RAM, CD-ROM, magnetic tape, floppy disk, flash drive, smart card, and optical data storage device.

Computer-readable playback media can be distributed over network coupled computer systems so that they can be stored and executed in a distributed fashion by, for example, a telematics server or a controller area network (CAN).

Hereinafter, a predictive maintenance management system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a conceptual diagram showing the configuration of a predictive maintenance management system according to an embodiment of the present invention.

As illustrated in FIG. 1, the predictive maintenance management system according to an exemplary embodiment of the present invention includes a plurality of production facilities 100, a programmable logic controller (PLC) device 200, a master PLC device 300, and an alarm server 400. ), A radio connection repeater 500, a plurality of radios 600, and a personal mobile terminal 700 displaying an alarm message.

The production equipment 100 refers to various equipment installed in a production line. For example, an automated robot provided in an assembly line of a vehicle, various inspection facilities provided in an inspection line, or various assembly facilities provided in an assembly line. Means. When a failure occurs in any part of the production facility 100, the production facility 100 generates an alarm signal. In this case, the alarm signal may be generated as an alarm bit.

The PLC device 200 is connected to the production facility 100 through a network (for example, serial communication such as RS-232), and through the input and output module, logical operation, sequence operation, timer, count, arithmetic operation, etc. It refers to an electronic device having a program for driving the production facility 100 by using a programmable memory to perform the control operation of. The alarm signal generated in the production facility 100 is provided to the master PLC device 300.

The master PLC device 300 determines a failure state of the production facility 100 through an alarm signal of the production facility 100 detected through the PLC device 200. In this case, the failure information on the failure state of the production equipment through the alarm signal is the location of the production line in which the production facility 100 is installed, the order in which the production facility 100 is installed, the location of the failure component in the production facility 100. , And information about the type of failure. In addition, the failure information may further include information about the manufacturer of the production equipment (for example, the Internet homepage of the manufacturer of the production equipment, the contact of the manufacturer, the contact of the maintenance person, etc.).

Specifically, the alarm signal (alarm bit) generated in the production facility 100 may be composed of a four-digit alarm bit of hexadecimal. Here, the first digit shows information about the production line, the second digit shows the order of the production equipment 100, the third digit shows information about the failure location of the production equipment 100, and The fourth digit can indicate information about the type of failure.

For example, it is assumed that the alarm signal is hexadecimal 'Ox1A6B'. At this time, it can be determined that the alarm signal has occurred in the production facility 100 provided in the first production line (eg, the assembly line) through the value 'Ox1000', which is the first digit of the alarm signal. In addition, it may be determined that the alarm signal is generated in the 10th assembly robot of the first production line through the value 'Ox0A00', which is the second digit of the alarm signal. In addition, it may be determined that the alarm signal is generated in the sixth driving motor through the value 'Ox0060', which is the third digit of the alarm signal. Finally, the eleventh type of failure (eg, failure due to wire shortage) can be determined through the value 'Ox00B', the fourth digit of the alarm signal.

As such, the failure state of the production facility 100 may be accurately determined through the alarm signal generated by the production facility 100.

The state of the production facility 100 determined by the master PLC device 300 is provided to the alarm server 400. The alarm server 400 converts a failure state of the production facility 100 provided from the master PLC device 300 into a voice and transmits it to the radio 600.

The alarm server 400 and the radio 600 are wirelessly connected through the radio connection repeater 500. At this time, the radio connection repeater 500 and the alarm server 400 may transmit and receive data through RS-232 communication.

The radio connection repeater 500 controls a push-to-talk (PTT) function of the radio 600 so that a voice signal transmitted from the alarm server 400 is transmitted to the radio 600. One radio connection repeater 500 can control up to five channels at the same time, and up to five radios 600 of different channels can be connected to each other. The voice signal transmitted from 400 may be transmitted.

The radio connection repeater 500 controls a push to talk (PTT) function for all or each of the radios 600 of up to five channels, and each channel of the radio connection repeater 500 is registered in the alarm server 400. One to one matching five alarm channels.

When the alarm signal occurs in the production facility 100, the alarm signal is converted into a voice signal in the alarm server 400, and is sent to the radio 600 connected to the channel matching the channel registered in the alarm server 400. . At this time, the voice signal transmitted from the alarm server 400 is the alarm signal of the production facility 100 is transmitted to the plurality of radios 600 connected to the same channel through the voice transmission signal of the radio.

The radio connection repeater 500 controls the PTT function of the radio 600 to be activated (or started) at the time when an alarm signal is generated in the production facility 100, and the voice signal transmitted from the alarm server 400 (ie, When the voice signal is generated), the PTT function is terminated.

When the alarm signal is generated in several places at the same time in the production facility 100, the radio connection repeater 500 controls the alarm signal generated in each production facility 100 to be sequentially transmitted to the radio (600).

As described above, since the alarm signal generated in the production facility 100 is 'Ox1A6B', when the alarm signal is converted into voice, the short circuit of the sixth drive motor of the tenth assembly robot of the first production line is disconnected. Is caused by a failure.

The voice converted by the alarm server 400 is transmitted to the radio 600 through the radio connection repeater 500, and the radio 600 outputs the voice converted by the alarm server 400. Therefore, the manager can determine which part of which part of which production facility 100 of which production line has failed due to the voice signal generated by the radio 600, and prepare a quick response plan for the failure situation. It becomes possible.

Meanwhile, the predictive maintenance management system according to the embodiment of the present invention may further include a personal portable terminal 700 connected to the alarm server 400 through a wireless network. The personal portable terminal 700 may refer to a personal portable terminal 700 which is a commercial service such as a smart phone or a tablet computer.

The alarm server 400 may generate an alarm character corresponding to the alarm signal. As described above, in response to the alarm signal generated in the production facility 100 generates a letter, 'Failure caused by a short circuit in the sixth drive motor of the tenth assembly robot of the first production line,' generated characters Is transmitted to the personal mobile terminal 700 (see FIG. 4).

The personal portable terminal 700 displays the text transmitted from the alarm server 400, thereby providing the manager with a failure situation of the production facility 100.

Here, the radio 600 is connected through short-range wireless communication, and is used in a limited area such as a factory in which the production facility 100 is installed, and the personal portable terminal 700 is an area outside the factory in which the production facility 100 is installed. Can also be used at

On the other hand, the alarm server 400 displays the alarm signal generated in the production facility 100 in real time, and records the history of the alarm signal for a certain period generated in the production facility 100 by a certain period unit (daily, monthly , And year by year) can be created to analyze the history of the alarm signal generated and store it in the database. The history of the alarm signal stored in the database may be selectively provided to the personal portable terminal 700.

That is, as shown in Figure 2, the administrator can easily look up the history of the alarm signal generated during the desired period through the personal portable terminal 700, and also when the failure situation occurs quickly You can arrange.

In addition, the alarm server 400 transmits a voice signal corresponding to the type of the alarm signal generated at the production facility 100 to the radio 600 or the personal portable terminal 700. That is, the voice signal according to the failure type determined by the fourth digit in the alarm signal is stored in advance in the alarm server 400. When a specific failure type occurs, the alarm server 400 transmits a voice signal according to the failure type to the radio 600 or the personal portable terminal 700, and the radio 600 or the personal portable terminal 700. Outputs the voice signal transmitted from the alarm server 400.

As such, since the voice signal output through the radio 600 or the personal portable terminal 700 is differently generated according to the type of failure, the administrator may output the voice signal output from the radio 600 or the personal portable terminal 700. Only the type of failure can be pinpointed.

Meanwhile, the alarm server 400 converts a failure state of the production equipment detected by the master PLC device 300 into failure information and transmits the failure information to the personal portable terminal 700, or transmits the failure information of the production equipment to a QR code. (The QR code, hereinafter referred to as an original QR code), and the like may be converted (see FIG. 5) and transmitted to the personal portable terminal 700. In this way, by transmitting the failure information to the QR code in the personal portable terminal 700, the maintenance personnel of the factory can directly access the homepage of the manufacturer of the production equipment through the personal portable terminal, or personally carry the maintenance personnel to the maintenance personnel. Wired contact via the terminal allows for quick maintenance of production facilities.

The personal portable terminal 700 may output a failure state of the production equipment transmitted from the alarm server 400 or output the original QR code.

At this time, the alarm server 400 generates an original QR code by using the failure information of the production equipment and transmits the original QR code to the personal portable terminal 700. In addition, an arbitrary QR code and a decoding capable of determining whether the original QR code is damaged or not are decoded. The QR code for the mobile device is generated together and transmitted to the personal mobile terminal 700.

Hereinafter, a process of generating an arbitrary QR code and a decoding QR code using the original QR code will be described.

FIG. 6 is a diagram illustrating a state in which one cell constituting the original QR code is divided into four mini cells according to an embodiment of the present invention. 7 and 8 are diagrams for describing a method for generating an arbitrary QR code and a decoding QR code according to an embodiment of the present invention.

6 to 8, the alarm server 400 generates the original QR code using the failure information, and then sets each cell constituting the original QR code to an even number (for example, 4) of mini cells. Generate a random QR code by partitioning, assigning one half of the four mini cells to one of two colors, and assigning the other half to the other half of the even mini cells as one color. can do.

In addition, the alarm server 400 divides the cells constituting the original QR code into even number of mini cells, assigns half of the even number of mini cells to any one of two colors, and the even number of mini cells. The random QR code may be generated by assigning the other half of the minicells to one other color.

In the embodiment of the present invention, the original QR code is a black and white QR code composed of white and black, and each cell constituting the original QR code may be divided into four mini cells. Therefore, the arbitrary QR code and the decoding QR code are also implemented as black and white QR codes. In the specification of the present invention, black and white are expressed as colors opposite to each other.

Referring to FIG. 6, after dividing one cell constituting the original QR code into four mini cells, two mini cells are allocated black and white color is allocated to the other two mini cells. You can create a cell. Through this process, random QR code is generated.

If the cell constituting the original QR code is black, the decoding code is allocated by assigning a color opposite to the color assigned to the mini cell of the arbitrary QR code to the mini cell of the decoding QR code corresponding to the mini cell of the arbitrary QR code. Can be generated. For example, as shown in FIG. 7, if black is allocated to a mini cell of an arbitrary QR code, white is allocated to the mini cell of the corresponding decoding QR code.

On the contrary, if the cell constituting the original QR code is white, the decoding cell is assigned the same color as the color assigned to the mini cell of the arbitrary QR code to the mini cell of the decoding QR code corresponding to the mini cell of the arbitrary QR code. You can generate code. For example, as shown in FIG. 7, if black is allocated to a mini cell of an arbitrary QR code, black is allocated to a mini cell of a corresponding QR code for decoding.

Through this process, an arbitrary QR code and a decoding QR code are generated.

The personal portable terminal 700 may determine whether the original QR code is damaged by combining the original QR code, the arbitrary QR code, and the decoding QR code transmitted from the alarm server 400.

That is, the personal mobile terminal 700 overlaps an arbitrary QR code partitioned into four mini cells and a decoding QR code partitioned into four mini cells, and if all the mini cells are black, the cell constituting the original QR code is determined to be black. can do.

In addition, the personal mobile terminal 700 overlaps an arbitrary QR code partitioned into four mini cells and a decoding QR code partitioned into four mini cells so that two mini-cells of all mini cells constitute a original QR code. It can be judged that it is white.

Through such a process, the personal mobile terminal 700 may determine whether the original QR code is damaged and transmitted.

Hereinafter, a predictive maintenance management method using the predictive maintenance management system according to an embodiment of the present invention as described above will be described in detail with reference to the accompanying drawings.

9 is a flowchart illustrating a predictive maintenance management method according to an embodiment of the present invention.

As shown in FIG. 9, the PLC device 200 detects an alarm signal generated in the production facility 100, and the detected alarm signal is transmitted to the master PLC device 300 (S10).

The master PLC device 300 determines the failure state of each production facility 100 from the alarm signal transmitted from the PLC device 200, and the failure state of the production facility 100 is transmitted to the alarm server 400 ( S20).

The alarm server 400 converts the failure state of the production equipment transmitted from the master PLC device 200 to the failure information or converts the failure information into the original QR code and transmits it to the personal portable terminal 700 (S30).

At this time, the alarm server 400 uses the original QR code to determine whether the original QR code transmitted to the personal portable terminal 700 is damaged. Can be generated and sent together.

Since the method of generating an arbitrary QR code and a decoding QR code using the original QR code is the same as described above, a detailed description thereof will be omitted.

The personal portable terminal 700 outputs a failure state (or failure information) of the production facility 100 transmitted from the alarm server 400 or outputs an original QR code (S40).

In this case, the personal portable terminal 700 may determine whether the original QR code transmitted from the alarm server 400 is damaged by using an arbitrary QR code and a decoding QR code.

Since the method of determining whether the original QR code is damaged using the arbitrary QR code and the decoding QR code is the same as described above, a detailed description thereof will be omitted.

Meanwhile, the alarm server 400 converts a failure type of the alarm signal into a voice signal, and converts the converted voice signal into a radio by a predetermined group (for example, a maintenance personnel group or a manufacturer personnel group of a production facility). Can be sent selectively.

According to the predictive maintenance management system according to the embodiment of the present invention as described above, it is possible to accurately determine the failure location and failure type of the production equipment through the alarm signal generated in the production equipment.

In addition, since information on the type of failure is transmitted to the manager through a voice signal transmitted to the radio or the personal portable terminal, the manager can quickly establish a countermeasure according to the type of failure of the production facility.

In addition, by transmitting the failure information of the production equipment to the personal portable terminal through the QR code, it is possible to quickly access the Internet homepage of the production equipment manufacturer, it is possible to quickly contact the maintenance personnel of the production equipment.

In addition, it is possible to determine whether the original QR code is damaged by using the arbitrary QR code and the decoding QR code, so that the original QR code transmitted from the alarm server to the personal mobile terminal due to an abnormal cause (for example, noise or hacking) can be determined. Can be restored

Various embodiments described herein may be implemented in a recording medium readable by a computer or similar device using, for example, software, hardware or a combination thereof.

According to a hardware implementation, the embodiments described herein include application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays (FPGAs), and the like. It may be implemented using at least one of processors, controllers, micro-controllers, microprocessors, and electrical units for performing other functions.

According to the software implementation, embodiments such as the procedures and functions described herein may be implemented as separate software modules. Each of the software modules may perform one or more functions and operations described herein. Software code may be implemented in software applications written in a suitable programming language.

Meanwhile, according to an embodiment of the present disclosure, the predictive maintenance management system described above may be implemented as a computer program including a series of instructions for performing a method or an apparatus. That is, the present invention may be a computer program running in a predetermined operating system, for example, a mobile operating system, and the program may process a process according to the series of instructions so that the method according to the present invention is implemented.

In another embodiment of the present invention, it may be a recording medium that can be read by a computer or similar electronic device, such as a floppy disk, a CD, a DVD, a hard disk memory, various types of memory, in which the computer program is stored. A computer or similar electronic device, such as a smart phone, which reads the computer program in the recording medium may perform the method according to the present invention according to the series of instructions on the computer program.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the scope of the invention.

Claims (23)

A plurality of production facilities provided in the production line;
A plurality of programmable logic controller (PLC) devices for controlling the plurality of production facilities and detecting alarm signals generated in the production facilities;
A master PLC device that determines a failure state of the plurality of production facilities from the alarm signal;
An alarm server for converting and transmitting a failure state of the production facility detected by the master PLC device into failure information or converting the failure information of the production facility into an original QR code (QR code); And
A personal portable terminal for outputting a failure state of the production facility transmitted from the alarm server or outputting the original QR code;
Prognosis maintenance management system comprising a. The method of claim 1,
The alarm server
The original QR code is generated using the failure information of the production facility and transmitted to the personal portable terminal, and an arbitrary QR code and a decoding QR code that can determine whether the original QR code is damaged are generated together with the individual. Predictive maintenance management system to transmit to the mobile terminal. The method of claim 2,
The alarm server
The cells constituting the original QR code are divided into even numbered minicells, and half of the even numbered minicells are assigned to one of two colors, and the other half of the even numbered minicells. Prognosis preservation management system for generating the random QR code by assigning a different color to. The method of claim 3,
The alarm server
And dividing the cells constituting the original QR code into even numbered mini cells, allocating the cells corresponding to the mini cell assigned to one color to another color, and assigning the mini cell assigned to the other color. A predictive maintenance management system which generates a decoding QR code by assigning a corresponding cell to any of the above colors. The method of claim 4, wherein
The personal mobile terminal
Predictive maintenance management system for determining whether the original QR code is damaged by combining the arbitrary QR code and the decoding QR code transmitted from the alarm server. The method of claim 5,
The personal mobile terminal
If the original QR code partitioned by an even number of mini cells and the decoding QR code partitioned by an even number of mini cells overlap each other and all the mini cells are of any one color, the cell of the original QR code is determined to be the one index. And if some minicells of all the minicells are of any one color, determine that the cell of the original QR code is the other index. The method of claim 1,
And the failure information includes information on the location of the production line in which the production facility is installed, the order in which the production facility is installed, the location of the failed part in the production facility, and the type of failure. The method of claim 1,
The alarm signal consists of four digit alarm bits,
The first digit displays information about a production line in which the production facility is installed,
The second digit indicates information about the order in which the production equipment is installed,
The third digit indicates information about a failure location of the production facility,
Prognostic maintenance management system, characterized in that the fourth digits display information on the type of failure. The method of claim 1,
The alarm server
A predictive maintenance management system for converting a failure type corresponding to the failure type of the alarm signal into a voice signal, and selectively transmitting the converted voice signal to a plurality of radios by a predetermined group. The method of claim 9,
A radio connection repeater wirelessly connected to the alarm server and the plurality of radios to control a push-to-talk function of the plurality of radios;
Prognosis conservation management system further comprising. The method of claim 10,
The radio connection repeater is a predictive maintenance management system that, when an alarm signal is generated in the production facility, a voice signal transmitted from the alarm server is transmitted to a radio connected to a channel matching the channel registered in the alarm server. The method of claim 11,
Prognosis maintenance management system for controlling the push-to-talk function of the radio is activated at the time when the alarm signal is generated in the production facility, and the push torque function is terminated when the voice signal transmitted from the alarm server is terminated. The method of claim 1,
The alarm server
Display the alarm signal generated in the production facility in real time, build the alarm signal in big data through the history management, analyze the history of the alarm signal generated by generating the alarm signal daily / month / year table Prognosis maintenance management system for transmitting to the personal portable terminal. Detecting, by a programmable logic controller (PLC) device, an alarm signal occurring at the production facility;
Determining, by the master PLC device, a failure state of the production facility from the alarm signal;
Converting, by an alarm server, the failure state of the production facility transmitted from the master PLC device into failure information or converting the failure information into an original QR code (QR code); And
Outputting, by the personal portable terminal, a failure state of the production facility transmitted from the alarm server or outputting the original QR code;
Prognosis maintenance management method comprising a. The method of claim 14,
In the transmitting step
The predictive maintenance management method of generating a random QR code and a decoding QR code that can determine whether the original QR code is damaged. The method of claim 15,
The cells constituting the original QR code are divided into even numbered minicells, and half of the even numbered minicells are assigned to one of two colors, and the other half of the even numbered minicells. Prognostic maintenance management method for generating the random QR code by assigning a different color to. The method of claim 16,
And dividing the cells constituting the original QR code into even numbered mini cells, allocating the cells corresponding to the mini cell assigned to one color to another color, and assigning the mini cell assigned to the other color. The predictive maintenance management method of generating a decoding QR code by assigning a corresponding cell to any one of said colors. The method of claim 17,
Determining, by the personal portable terminal, whether the original QR code is damaged by combining the arbitrary QR code transmitted from the alarm server and the decoding QR code;
Prognosis maintenance management method further comprising. The method of claim 18,
If the original QR code partitioned by an even number of mini cells and the decoding QR code partitioned by an even number of mini cells overlap each other and all the mini cells are of any one color, the cell of the original QR code is determined to be the one index. And determining that a cell of the original QR code is the other index if some of the mini cells are all one color. The method of claim 14,
And the failure information includes information on a location of a production line in which the production facility is installed, an order in which the production facility is installed, a location of a failure part in the production facility, and a failure type. The method of claim 14,
The alarm signal consists of four digit alarm bits,
The first digit displays information about a production line in which the production facility is installed,
The second digit indicates information about the order in which the production equipment is installed,
The third digit indicates information about a failure location of the production facility,
The predictive maintenance management method according to claim 4, wherein the fourth digit displays information on the type of failure. The method of claim 14,
Converting, by the alarm server, a failure type of the alarm signal into a voice signal, and selectively transmitting the converted voice signal to a radio by a predetermined group;
Prognosis maintenance management method further comprising. The method of claim 14,
An alarm generated by the alarm server to display the alarm signal generated in the production facility in real time, construct the alarm signal as big data through history management, and generate the alarm signal in a daily / monthly / yearly table Predictive maintenance management method for analyzing the history of the signal and transmitting to the personal portable terminal.

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