JP5085060B2 - Alarm processing apparatus, program thereof, and alarm processing method - Google Patents

Description

  The present invention relates to an alarm processing device, a program thereof, and an alarm processing method, and more particularly to an alarm processing device that handles a plurality of alarms, a program thereof, and an alarm processing method.

A conventional alarm processing device stores a voice message or a display message corresponding to an alarm signal source, an abnormality type, and an alarm level, and when an alarm signal is received, the stored voice message or display message is stored. The voice message or display message corresponding to the received alarm signal is read out and output. In addition, when a plurality of alarm signals are received, the voice message or display message corresponding to the source of the plurality of alarm signals, the abnormality type, and the alarm level is stored, and when a plurality of alarm signals are received, A voice message or a display message is read out from these and output (for example, refer to Patent Document 1).
JP 2005-234695 A

  However, in the conventional alarm processing device, when a large number of alarms are generated, since many alarm voice messages or display messages are output, important alarms are buried in these alarms. There is a problem that the user who listens to or sees the alarm cannot know which alarm is an important alarm.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide an alarm processing device that can output important alarms in an easily understandable manner even when a large number of alarms are generated.

The present invention has been made to solve the above-described problem, and the alarm processing device of the present invention monitors an external device connected via a communication line and acquires an alarm instruction; and The alarm instruction acquired by the monitoring processing unit is stored in the storage unit, the reproduction order determination processing unit for selecting the alarm instruction with the highest priority among the alarm instructions stored in the storage unit, the alarm sound data and the broadcast range An alarm storage unit that stores information in association with each other, and generates an audio signal by reproducing the alarm audio data corresponding to the alarm instruction selected by the reproduction order determination processing unit, and corresponds to the reproduced alarm audio data put in, characterized in that it comprises a sound reproduction processor for outputting the audio signal to an external device together with information indicating the broadcasting range where the alarm storage unit stores.

  Thereby, the alarm processing device of the present invention outputs the sound signal of the alarm sound data corresponding to the alarm instruction with the highest priority among the stored alarm instructions, in order from the alarm instruction with the highest priority, Outputs the audio signal of the corresponding alarm audio data. For this reason, the alarm processing device of the present invention can output the sound of an important alarm instruction so that it can be easily understood even when a large number of alarm instructions are generated.

  The alarm processing device of the present invention is the above-described alarm processing device, wherein the priority is based on a priority level of the alarm instruction.

  Thereby, since the alarm processing device of the present invention outputs the audio signal of the alarm audio data corresponding to the alarm instruction with the highest priority level among the stored alarm instructions, in order from the alarm instruction with the highest priority level, Outputs the audio signal of the corresponding alarm audio data. For this reason, the alarm processing device of the present invention can output the sound of an important alarm instruction so that it can be easily understood even when a large number of alarm instructions are generated.

Further, the alarm processing device of the present invention is the above-described alarm processing device, wherein the reproduction order determination processing unit excludes alarm instructions stored in the storage unit, which have been reproduced and being reproduced. An alarm instruction other than the alarm instruction having the highest priority level among the unreproduced alarm instruction and the alarm instruction acquired by the monitoring processing unit is deleted from the storage unit.

  Thereby, the alarm processing device of the present invention outputs only the audio signal of the alarm audio data corresponding to the alarm instruction having the highest priority level among the stored alarm instructions, so that when a large number of alarm instructions occur However, it can output important alarm instructions in a way that is easy to understand.

  Further, the alarm processing device of the present invention is the above-described alarm processing device, wherein the reproduction order determination processing unit stores the alarm instruction acquired by the monitoring processing unit in the storage unit. When the priority level of the alarm instruction corresponding to the alarm sound data being reproduced is lower than the acquired alarm instruction, the sound reproduction processing unit is instructed to stop the reproduction of the alarm sound data.

  Thus, the alarm processing device of the present invention, when outputting an audio signal of the alarm audio data, issues an alarm instruction having a higher priority level than the alarm instruction corresponding to the alarm audio data of the output audio signal. When detected, the alarm sound data being output is stopped and the sound signal of the alarm sound data corresponding to the detected alarm instruction is output, so even when a large number of alarm instructions occur, the sound of important alarm instructions can be understood. Can be output easily.

Further, the program of the present invention monitors the external device connected via a communication line and acquires a warning instruction by a computer, and stores the warning instruction acquired by the monitoring processing part in a storage unit. of the alarm instructions stored in the storage unit, reproduction order determination processing unit that selects the highest priority alarm command to play the alarm sound data corresponding to the reproduction order determination processing unit selected alarm indication It generates audio signals, to function as an audio reproduction processing unit which outputs the audio signal together with information indicating the broadcast range storage unit in association with alarm sound data the reproduction is stored in the external device.

Further, the alarm processing method of the present invention is the alarm processing method in the alarm processing apparatus in which the external device is connected via a communication line, the first process of monitoring the external device and acquiring the alarm instruction, The alarm instruction acquired in the first process is stored in the storage unit, and the alarm process stored in the storage unit is selected in the second process and the second process of selecting the alarm instruction having the highest priority. play alarm sound data corresponding to the alarm instruction selected to generate an audio signal Te, it outputs the audio signal together with information indicating the broadcast range storage unit in association with alarm sound data the reproduction is stored in an external device And a third process.

  According to the present invention, since the audio signals of the corresponding alarm audio data are output in order from the alarm instruction with the highest priority, even when a large number of alarm instructions are generated, the audio of important alarm instructions is output so that it can be easily understood. Therefore, even when a large number of alarms occur, it is possible to output important alarms so that they can be easily understood.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic block diagram showing a configuration of an alarm system installed in a factory or the like using an alarm processing device 100 according to an embodiment of the present invention.

  The alarm processing device 100 detects an alarm instruction generated by a PLC (Programmable Logic Controller) 300a, 300b, reproduces alarm audio data based on the alarm instruction, generates an audio signal, and transmits the audio signal from the speaker terminal to the monitor speaker 500. In addition, the signal is output from the LINEOUT terminal to the in-house broadcasting facility 600. Further, by connecting the on-site broadcasting facility 600 to the contact output terminal together with the LINEOUT terminal, the alarm processing device 100 can instruct the broadcast range of the alarm sound.

Reference numeral 200 denotes a memory card that stores a device definition file, a PLC definition file, an alarm sound data definition file, an alarm definition file, and a word sound data file, and is inserted into the alarm processing device 100. The user can set the operation of the alarm processing device 100 by creating or editing the above-described files using a PC or the like, storing the files in the memory card 200, and inserting the files into the alarm processing device 100.
Details of each file described above will be described later.

PLCs (external devices) 300a and 300b are programmable logic controllers that receive inputs from gas sensors 400a and 400b installed at various locations in the factory and generate alarm instructions. The alarm instruction is generated by setting a flag on a specific bit of a specific address in a memory in the PLC 300a or 300b. Bits of addresses to be flagged are allocated according to the type and location of the detected gas, and the PLCs 300a and 300b are assigned to the corresponding address bits according to the gas and installation location detected by the gas sensors 400a and 400b. Set a flag.
The gas sensors 400a and 400b are sensors that detect toxic gases and the like. In the present embodiment, since an alarm processing system that detects gas and issues an alarm is described as an example, a gas sensor is used. However, the equipment controlled by the PLCs 300a and 300b is monitored to detect abnormality of the equipment. If it is an alarm processing system that detects and issues an alarm, an abnormality such as a failure of equipment controlled by the PLCs 300a and 300b may be detected.

  The monitor speaker 500 is connected to the speaker terminal of the alarm processing device 100, and sounds the alarm sound output from the alarm processing device 100.

  The on-site broadcasting facility 600 is connected to the LINEOUT terminal and the contact output terminal of the alarm processing device 100, and the alarm sound output from the alarm processing device 100 is sounded by the speakers 700a and 700b. The on-site broadcasting facility 600 selects the speaker to be sounded according to the BUSY signal output from the contact output terminal when sounding the alarm sound.

  The speakers 700a and 700b are speakers installed in various places in the factory.

Reference numeral 800 denotes a LAN (Local Area Network) that connects the alarm processing device 100 and the PLCs 300a and 300b.
FIG. 2 is a schematic block diagram illustrating a configuration of the alarm processing device 100 according to the present embodiment.

  Reference numeral 110 denotes a CPU (Central Processing unit) that controls the alarm processing apparatus 100, and includes an initial processing unit 111, a monitoring processing unit 112, a reproduction order determination processing unit 113, and an audio reproduction processing unit 114.

  When the alarm processing device 100 is turned on, the initial processing unit 111 initializes each unit, reads a file stored in the memory card 200, and stores the file in the file storage unit 121 of the memory 120.

  The monitoring processing unit 112 periodically monitors the alarm instruction flag in the PLCs 300 a and 300 b via the LAN 800 and stores the detected alarm instruction in the work area unit 122 of the memory 120. The PLC to be monitored and its address and bit are selected based on the PLC definition file and alarm definition file stored in the file storage unit 121.

  The reproduction order determination processing unit 113 selects an alarm instruction to be preferentially output from the alarm instructions stored in the work area unit 122, and instructs the audio reproduction processing unit 114 to perform reproduction. The playback order determination processing unit 113 will be described in detail in the description of the operation.

  In response to the reproduction instruction from the reproduction order determination processing unit 113, the audio reproduction processing unit 114 reproduces alarm audio data corresponding to the corresponding alarm instruction. The alarm sound data to be reproduced is generated based on the alarm sound data definition file, the alarm definition file, and the word sound data file stored in the file storage unit 121.

  The memory 120 includes a ROM (Read Only Memory) storing a program for operating the CPU 110 and a RAM (Random Access Memory) serving as a work memory when the CPU 110 operates. The RAM includes a file storage unit 121 and a work. An area unit (storage unit) 122. Details of the work area unit 122 will be described later.

  A LAN controller unit 130 is connected to the LAN 800 and controls communication.

  Reference numeral 140 denotes a memory card interface unit that is connected to the memory card 200 inserted into the alarm processing device 100 and controls reading of files from the memory card 200 and writing of files to the memory card 200.

  A display / input / output interface unit 150 controls an LED (Light-Emitting Diode) display unit 151 and a contact input / output unit 152.

  The LED display unit 151 includes a two-digit 7-segment LED display that displays the operation status of the alarm processing device 100 based on the control of the CPU 110 via the display / input / output interface unit 150.

  The contact input / output unit 152 outputs 8-point BUSY signal contact outputs based on the control of the CPU 110 via the display / input / output interface unit 150, and interrupt signal contact inputs to the CPU 110 via the display / input / output interface unit 150. Is provided.

Reference numeral 160 denotes an alarm sound reproduction D / A converter unit that converts a digital signal of the alarm sound data reproduced by the sound reproduction processing unit 114 into an analog signal and outputs the analog signal to the electronic volume units 161 and 162.
The electronic volume units 161 and 162 are variable resistors controlled by the CPU 110.
Reference numeral 163 denotes a speaker amplifier that amplifies the analog signal of the alarm sound.

  A file storage unit 201 stores a device definition file, a PLC definition file, an alarm sound data definition file, an alarm definition file, and a word sound data file.

FIG. 3 is a diagram illustrating items set in the device definition file and examples of setting contents.
No. The pause number of 1 (0 to 7) is the number of seconds of the silent part to be inserted when the sound reproduction processing unit 114 reproduces the alarm sound data.
No. The sampling period (1 to 60) seconds of 2 is the number of seconds of the period for monitoring the alarm instruction flag in the PLCs 300a and 300b.
No. The presence / absence of reference to priority level 3 (0: no, 1: yes) indicates that when a plurality of alarm instructions are detected continuously or simultaneously, the alarm instruction is generated as an alarm instruction to be reproduced as a process of the reproduction order determination processing unit 113. This is information for determining whether to select in order (0: none) or whether to change the order based on the priority level (1: present).

No. 4 indicates whether or not there is a message stop process during playback (0: no, 1: yes) when the alarm instruction is detected, the alarm voice data corresponding to the alarm instruction having a lower priority level than the detected alarm instruction is being reproduced. In this case, the reproduction order determination processing unit 113 is information for determining whether to stop reproduction of the alarm sound data (1: present) or not (0: absent).
No. The presence or absence of alarm deletion processing with a low priority of 5 (0: no, 1: yes) does not reproduce alarm voice data corresponding to an alarm instruction having a lower priority level than the detected alarm instruction when an alarm instruction is detected. As described above, among the alarm instructions registered in the work area unit 122, the reproduction order determination processing unit 113 deletes an alarm instruction having a lower priority level than the detected alarm instruction (1: present) or not (0). : None).

No. Nine networks (1 to 127) are PLC network numbers to which the alarm processing device 100 belongs.
No. Ten nodes (1 to 126) are node numbers that are numbers for identifying the alarm processing device 100 in the PLC network.
No. The IP address 11 is the IP address of the own device.
No. The subnet mask 12 is the subnet mask of the LAN 800 to which the own device is connected.
No. The default gateway 13 is the IP address of the default gateway of its own device.

FIG. 4 is a diagram illustrating items set in the PLC definition file and setting content examples.
The PLC definition file is a file that defines items related to the PLCs 300a and 300b to be monitored by the monitoring processing unit 112. In the example shown in FIG. 4, eight PLCs to be monitored are set.
PLC_No is a serial number that identifies the PLC.
The PC type is a type of PLC. The monitoring processing unit 112 generates a command for monitoring an alarm instruction based on the PC type.

The network is a network number for the PLC to which the PLC belongs.
The node is a node number of a number for identifying the PLC in the PLC network.
The IP address is the IP address of the PLC.
The port number is a destination port number to which the monitoring processing unit 112 transmits a command for monitoring an alarm instruction.
The number of retransmissions is the number of retransmissions when the command used when the monitoring processing unit 112 monitors an alarm instruction times out.
The time-out time (ms) is the time in milliseconds that the monitoring processing unit 112 regards as a time-out when a command for monitoring an alarm instruction is transmitted and no response is returned.

FIG. 5 is a diagram showing items set in the alarm sound data definition file and examples of setting contents.
The alarm sound data definition file is a file that defines word codes constituting the alarm sound data reproduced by the sound reproduction processing unit 114. By combining an appropriate word code, the content of the alarm sound data can be changed to a sentence suitable for the purpose of the alarm. In the example of FIG. 5, word codes constituting one alarm sound data are defined in each row, and a total of 11 alarm sound data are defined.
The alarm sound No (1 to 5000) is a serial number for identifying alarm sound data.
Word numbers 1 to 8 are word codes constituting the alarm sound data. The audio reproduction processing unit 114 sequentially reproduces the word codes of word number 1 to word number 8. However, the word code larger than “FE01” sets the pattern of the BUSY signal output from the contact input / output unit 152, not the voice to be reproduced. Since there are 8 contacts that output the BUSY signal, there are 255 patterns in total for the BUSY signal patterns depending on the combination of the presence or absence of output at these 8 points.

FIG. 6 is a diagram showing items set in the alarm definition file and setting content examples.
The alarm definition file defines an alarm instruction (PLC_No and PLC memory address) monitored by the monitoring processing unit 112 and alarm sound data (alarm sound No) generated by the sound reproduction processing unit 114 in response to the alarm instruction. It is a file.
In the example shown in FIG. 6, one alarm instruction is defined for each row, and a total of six alarm instructions are defined.

The group number and the signal number are numbers that identify alarm instructions that are unique by combining them.
The alarm sound No (1 to 5000) is the alarm sound No. of the alarm sound data corresponding to the alarm instruction.
The priority level (0 to 7) is the priority level of the warning instruction. In the present embodiment, the priority level is higher when the value is greater than 0-7 and the value is larger.
The number of repetitions (0 to 7) is the number of times that the alarm sound data is reproduced when the alarm instruction is detected.
PLC_No (1 to 16) is the PLC_No of the PLC to be monitored.
The memory address in the PLC is an address or bit in the PLC to be monitored.

FIG. 7 is a diagram showing items set in the word voice data file and setting content examples.
The word voice data file is a file that defines voice data of each word code. In FIG. 7, the voice data is represented by characters, but is stored in a file in a format such as PCM (Pulse Code Modulation).

  FIG. 8 is a diagram showing an example of stored contents of the work area unit 122 of the memory 120. The work area unit 122 stores the alarm instruction group No., signal No. (defined in the alarm definition file (FIG. 6)) detected by the monitoring processing unit 112, and the status of the alarm instruction in the order in which the alarm instructions are detected. ing. The alarm instruction states include “unreproduced” and “reproducing”, and two or more alarm instructions are not “reproduced” at the same time. Therefore, instead of providing a status item in each row as shown in FIG. 8, an area for storing a “reproducing” alarm instruction is provided, and the second alarm instruction is “reproducing” as in FIG. In some cases, “2” indicating the second in the work area portion 122 may be stored in the area.

FIG. 9 is a flowchart for explaining the operation of the alarm processing device 100 of the present embodiment.
First, when the power of the alarm processing device 100 is turned on, the initial processing unit 111 receives a device definition file, a PLC definition file, alarm sound data from the file storage unit 201 of the memory card 200 via the memory card interface unit 140. The definition file, the alarm definition file, and the word voice data file are read and stored in the file storage unit 121 of the memory 120 (S1). Thereafter, when each processing unit refers to each of the files described above, the file stored in the file storage unit 121 is referred to. Next, the initial processing unit 111 determines whether all the above-described files have been read (S2). If it is determined that there is a file that has not been read, the initial processing unit 111 instructs the LED display unit 151 to display an error number via the display / input / output interface unit 150 (S3). Here, if all the files are read, the determination condition is satisfied, and the initial processing unit 111 initializes each unit of the alarm processing device 100 (S4).

  Next, the monitoring processing unit 112 instructs the LAN controller unit 130 to transmit a command for acquiring the values of the memory addresses in the PLC_No of all PLCs defined in the alarm sound data definition file. When the monitoring processing unit 112 receives a response to the command via the LAN controller unit 130, the monitoring processing unit 112 confirms the content of the response, and checks the group No. corresponding to the memory address in the PLC_No in which the alarm instruction flag is set. A notification including the pair with the signal No is output to the reproduction order determination processing unit 113 (S6). Here, in the response, assuming that PLC_No is “1” and the memory address in PLC is “dDM036011: 01”, the monitoring processing unit 112 refers to the alarm definition file. When the alarm definition file has the content example shown in FIG. 6, the group No. “1” and signal No. “1” corresponding to the alarm instruction (PLC_No “1”, PLC memory address “dDM03601: 01”) Output a notification that contains.

  When receiving the notification, the reproduction order determination processing unit 113 determines whether or not a group of the alarm instruction group No and signal No is included in the notification (S7). When it is determined that it is not included, the process proceeds to step S14. Here, since the notification includes a set of group No “1” and signal No “1”, it is determined that it is included. The process proceeds to step S8. In step S8, the reproduction order determination processing unit 113 extracts a warning instruction of a group No. “1” and a signal No. “1” from the received notification and stores it in the work area unit 122 (S8).

  Next, the reproduction order determination processing unit 113 sets the priority level of the alarm instruction stored in the work area unit 122 and the alarm instruction stored in the work area unit 122 and in the state of “reproducing” in the alarm definition file. Get from. The playback order determination processing unit 113 stores No. 1 in the device definition file. The presence / absence of reference to priority level 3 (0: no, 1: present) is set to “1”, and the priority levels of these two alarm instructions are compared and stored in the former work area section 122. It is determined whether or not the issued warning instruction has a higher priority level than the latter “reproducing” warning instruction (S9). If the determination condition is not satisfied, the process proceeds to step S12. The presence / absence of reference to priority level 3 (0: no, 1: present) is set to “1”, and the priority level of the former alarm instruction is “5”. The priority level is “4”, and it is assumed that the former priority level is higher and the determination condition of step S9 is satisfied.

  When the determination condition in step S9 is satisfied, the process proceeds to step S10, in which the reproduction order determination processing unit 113 refers to the device definition file and determines No. It is determined whether or not the message stop processing during reproduction of No. 4 (0: no, 1: present) is set to “1” (S10). If the determination condition is not satisfied, the process proceeds to step S12. The presence / absence of “1” is set in the presence / absence of message stop processing during reproduction of 4 (0: no, 1: yes), and it is assumed that the determination condition in step S10 is satisfied and the process proceeds to step S11. In step S <b> 11, the reproduction order determination processing unit 113 instructs the audio reproduction processing unit 114 to stop the reproduction of the alarm audio data, and deletes the alarm instruction whose state is “reproducing” from the work area unit 122. When receiving the instruction to stop the reproduction, the audio reproduction processing unit 114 stops the reproduction of the alarm voice data being reproduced (S11).

  The reproduction order determination processing unit 113 refers to the device definition file to determine the No. It is determined whether or not the presence / absence of alarm deletion processing with a low priority of 5 (0: no, 1: present) is set to “1” (S12). If the determination condition is not satisfied, the process proceeds to step S14. It is assumed that “1” is set in the presence / absence of alarm deletion processing with a low priority of 5 (0: no, 1: yes), the determination condition in step S12 is satisfied, and the process proceeds to step S13. In step S13, the reproduction order determination processing unit 113 is an alarm instruction stored in the work area unit 122, except for an alarm instruction having the highest priority level and an alarm instruction having a state of “reproducing”. Is deleted (S13).

  The playback order determination processing unit 113 determines whether or not the audio playback processing unit 114 has finished playback of the alarm instruction stored in the work area unit 122 and whose status is “Now Playing”. An inquiry is made with the group number and signal number. When the voice reproduction processing unit 114 receives the inquiry, it confirms the processing state of its own processing unit, and if there is an alarm instruction being reproduced, the group of the alarm instruction group No and the signal No. It is confirmed whether or not the set matches the signal No. The voice reproduction processing unit 114 responds that the reproduction is in progress when they match, and responds that the reproduction has been completed when they do not match or there is no warning instruction during reproduction. The reproduction order determination processing unit 113 deletes the alarm instruction in which the state stored in the work area unit 122 is “being reproduced” only when the reproduction is received from the audio reproduction processing unit 114 (S14).

  Next, the reproduction order determination processing unit 113 checks whether or not there is an alarm instruction stored in the work area unit 122 (S15). When there is no alarm instruction, the process proceeds to step S6, and the same processing as described above is repeated. When there is an alarm instruction, the process proceeds to step S <b> 16, and the reproduction order determination processing unit 113 checks whether the alarm instruction stored in the work area unit 122 includes an alarm instruction whose state is “being reproduced”. (S16). When there is an alarm instruction with the status “reproducing”, the process proceeds to step S6 and the same processing as described above is repeated. If there is no alarm instruction with the status “reproducing”, the process proceeds to step S17, where the device definition file No. It is determined whether or not “1” is set in the presence / absence of reference to the priority level 3 (0: not present, 1: present) (S17). When “0” is not set and the determination condition is not satisfied, the process proceeds to step S 19, where the reproduction order determination processing unit 113 displays the alarm instruction stored at the head of the work area unit 122. The group No. and signal No. pair is output to the audio reproduction processing unit 114 to instruct the reproduction of the alarm instruction and store “Now Reproducing” in the state of the alarm instruction (S19). ”Is set and the determination condition is satisfied.

  If the determination condition in step S17 is satisfied, the process proceeds to step S18, and the reproduction order determination processing unit 113 acquires the priority level corresponding to the alarm instruction stored in the work area unit 122 from the alarm definition file. The group of the alarm instruction group No. and signal No. having the highest priority level is output to the audio reproduction processing unit 114 to instruct the reproduction of the alarm instruction. The reproduction order determination processing unit 113 updates the state of the alarm instruction that has instructed reproduction to “being reproduced”, transitions to step S6, and repeats the same processing as described above (S18).

  On the other hand, when the audio reproduction processing unit 114 receives a set of group No and signal No as a reproduction instruction from the reproduction order determination processing unit 113, the audio reproduction processing unit 114 refers to the alarm definition file and sets the received group No and signal No. The alarm sound No and the number of repetitions corresponding to the set are acquired. Here, assuming that the combination of the received group No and signal No is group No “1” and signal No “1”, and the content of the alarm definition file is the content example shown in FIG. Obtains the alarm sound No “4” and the repetition number “2”.

  Next, the sound reproduction processing unit 114 refers to the alarm sound data definition file and acquires all the word codes corresponding to the alarm sound No “4”. Here, if the content of the alarm sound data definition file is the content example shown in FIG. 5, the sound reproduction processing unit 114 performs “FE04”, “0002”, “0035”, “0066”, “0037”, “0037” All the six word codes “0098” are acquired. Next, the sound reproduction processing unit 114 sequentially acquires sound data corresponding to these word codes from the word sound data file, reproduces the sound data, and announces an alarm sound. For example, when the first word code is “0002” and the content of the word audio data file is the content example shown in FIG. 7, the audio reproduction processing unit 114 reads “2nd floor clean room ○○○ from the word audio data file. The voice data of the voice “in the area” is acquired and played back, the voice data of the next word code is further acquired and played back, and the same processing is repeated for all the acquired word codes. However, since the first word code “FE04” is larger than “FE00”, it is an instruction to output a BUSY signal, and the audio reproduction processing unit 114 is connected to the contact input / output unit 152 via the display / input / output interface unit 150. Then, a BUSY signal is output to the on-site broadcasting facility 600. Although the value of the BUSY signal depends on the word code, in this embodiment, the value of the last two digits of the hexadecimal number of the word code is output. Upon receiving the BUSY signal, the on-site broadcasting facility 600 selects a speaker that sounds a sound according to the value of the BUSY signal.

  Next, the audio reproduction processing unit 114 receives the No. of the device definition file. The value set for one pause second (0 to 7) seconds is acquired, and after the set number of seconds has elapsed, the audio data corresponding to the second and subsequent word codes are reproduced in order. The digital signal is output to the alarm sound reproduction D / A converter unit 160. The audio reproduction processing unit 114 repeats the reproduction of the audio data in the same manner for the number of repetitions “2” previously obtained from the alarm definition file.

  When receiving the digital signal from the audio reproduction processing unit 114, the alarm audio reproduction D / A converter unit 160 converts the digital signal into an analog signal and outputs the analog signal to the electronic volume units 161 and 162. When receiving the analog signal, the electronic volume unit 161 converts the signal level according to the set resistance value, and outputs the signal level to the on-site broadcasting facility 600 from the LINEOUT terminal. Further, when receiving an analog signal, the electronic volume unit 162 converts the signal level according to the set resistance value and outputs the signal level to the speaker amplifier unit 163. When the speaker amplifier 163 receives the analog signal, it amplifies it and outputs it to the monitor speaker 500 from the speaker terminal.

  In this way, the device definition file No. When the value set to the presence / absence of priority level reference 3 (0: no, 1: present) is changed, the reproduction order determination processing unit 113 is detected by determining the value in step S17 described above. The alarm instruction is selected in order, and the corresponding alarm sound data is reproduced by the sound reproduction processing unit 114 (S19). The alarm instruction is selected in descending order of priority level, and the corresponding alarm sound data is transmitted to the sound reproduction processing unit 114. It can also be played back (S18). In the case of a system whose importance changes depending on the content of occurrence, the device definition file number If the priority level reference of 3 is set to “1” in the presence / absence of the priority level reference (0: no, 1: present), and the first alarm is important and the system has a high priority, No. By setting “3” as the presence / absence of priority level reference (0: no, 1: present) to “0”, it is possible to reproduce from an important alarm.

  In this way, the device definition file No. If the presence / absence of “1” is set in the presence / absence of message stop processing during playback (0: no, 1: yes), the audio playback processing unit determines the setting in step S10 described above. When the monitoring processing unit 112 detects an alarm instruction with a higher priority level while the alarm sound data is being reproduced by the 114, the reproduction order determination processing unit 113 causes the audio reproduction processing unit 114 to stop reproduction (S11). The alarm sound data corresponding to the detected alarm instruction can be preferentially reproduced. Thereby, the reproduction order determination processing unit 113 can cause the audio reproduction processing unit 114 to reproduce the alarm audio data corresponding to the detected alarm instruction without waiting for the completion of the reproduction of the alarm audio data having a low priority level. .

  In this way, the device definition file No. If the presence of “1” is set in the presence / absence (0: none, 1: present) of the alarm deletion process with a low priority of 5, the reproduction order is determined by determining the setting in step S12 described above. The processing unit 113 deletes the alarm instructions other than the alarm instruction with the highest priority level among the alarm instructions stored in the work area unit 122. For this reason, when the priority level is higher than the detected alarm instruction stored in the work area unit 122, the detected alarm instruction is deleted from the work area unit 122 (that is, not stored). When the priority level is lower than the detected warning instruction stored in the work area unit 122, the warning instruction stored in the work area unit 122 is deleted from the work area unit 122. Thereby, the reproduction order determination processing unit 113 can select the alarm instruction having the highest priority level among the detected alarm instructions, and the reproduction order determination processing unit 113 can reproduce the corresponding alarm sound data.

  Further, the program for realizing the functions of the initial processing unit 111, the monitoring processing unit 112, the reproduction order determination processing unit 113, and the audio reproduction processing unit 114 in FIG. 2 is recorded on a computer-readable recording medium. The processing of each processing unit may be performed by causing the computer system to read and execute the program recorded on the computer. Here, the “computer system” includes an OS and hardware such as peripheral devices.

Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Furthermore, the “computer-readable recording medium” dynamically holds a program for a short time like a communication line when transmitting a program via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory in a computer system serving as a server or a client in that case, and a program that holds a program for a certain period of time are also included. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes design and the like within a scope not departing from the gist of the present invention.

  The present invention is suitable for use in an alarm processing apparatus of an alarm processing system in which sensors are installed in a wide range such as in a factory and a toxic gas is detected to generate an alarm, but is not limited thereto.

It is a schematic block diagram which shows the structure of the alarm processing system using the alarm processing apparatus 100 by one Embodiment of this invention. It is a schematic block diagram which shows the structure of the alarm processing apparatus 100 in the embodiment. It is the figure which showed the item and the example of a setting content which are set with the apparatus definition file in the same embodiment. It is the figure which showed the example of the setting content set by the item of the PLC definition file in the same embodiment. It is the figure which showed the item and the example of a setting content which are set by the alarm sound data definition file in the embodiment. It is the figure which showed the item and the example of a setting content which are set with the alarm definition file in the embodiment. It is the figure which showed the item and the example of a setting content which are set with the word audio | voice data file in the embodiment. It is the figure which showed the example of the memory content of the work area part 122 of the memory 120 in the embodiment. It is a flowchart explaining operation | movement of the alarm processing apparatus 100 in the embodiment.

Explanation of symbols

100 ... alarm processor 110 ... CPU
DESCRIPTION OF SYMBOLS 111 ... Initial processing part 112 ... Monitoring processing part 113 ... Playback order determination processing part 114 ... Audio | voice reproduction | regeneration processing part 120 ... Memory 121 ... File storage part 122 ... Work area part 130 ... LAN controller part 140 ... Memory card interface part 150 ... Display / Input / output interface unit 151 ... LED display unit 152 ... Contact input / output unit 160 ... D / A converter unit for alarm sound reproduction 161, 162 ... Electronic volume unit 163 ... Speaker amplifier unit 200 ... Memory card 201 ... File storage unit 300a, 300b ... PLC
400a, 400b ... gas sensor 500 ... monitor speaker 600 ... on-site broadcasting equipment 700a, 700b ... speaker

Claims (6)

A monitoring processing unit for monitoring an external device connected via a communication line and obtaining an alarm instruction;
The alarm instruction acquired by the monitoring processing unit is stored in the storage unit, and the reproduction order determination processing unit that selects the alarm instruction with the highest priority among the alarm instructions stored in the storage unit;
An alarm storage unit that stores alarm audio data and information indicating a broadcast range in association with each other;
Along with information indicating the broadcast range stored in the alarm storage unit in association with the reproduced alarm audio data, the alarm audio data corresponding to the alarm instruction selected by the reproduction order determination processing unit is reproduced to generate an audio signal. An alarm processing device comprising: an audio reproduction processing unit that outputs the audio signal to an external device.   The alarm processing apparatus according to claim 1, wherein the priority is based on a priority level of the alarm instruction.   The reproduction order determination processing unit is an alarm instruction stored in the storage unit, and is the highest priority level among unreproduced alarm instructions excluding those being reproduced and the alarm instruction acquired by the monitoring processing unit The alarm processing device according to claim 2, wherein an alarm instruction other than a high alarm instruction is deleted from the storage unit.   When the reproduction order determination processing unit stores the alarm instruction acquired by the monitoring processing unit in the storage unit, the priority level of the alarm instruction corresponding to the alarm audio data being reproduced by the audio reproduction processing unit is 3. The alarm processing device according to claim 2, wherein when the alarm instruction is lower than the alarm instruction, the audio reproduction processing unit is instructed to stop reproducing the alarm audio data. Computer
A monitoring processing unit for monitoring an external device connected via a communication line and obtaining an alarm instruction;
The alarm instruction acquired by the monitoring processing unit is stored in a storage unit, and the playback order determination processing unit that selects the alarm instruction with the highest priority among the alarm instructions stored in the storage unit,
The audio together with information indicating the broadcast range in which the reproduction order determination processing unit generates a sound signal by reproducing the alarm sound data corresponding to the alarm instruction selected storage unit in association with alarm audio data the playback stores A program for functioning as an audio playback processor that outputs signals to an external device . In an alarm processing method in an alarm processing device in which an external device is connected via a communication line,
A first step of monitoring the external device and obtaining an alarm indication;
Storing the alarm instruction acquired in the first process in the storage unit, and selecting the alarm instruction having the highest priority among the alarm instructions stored in the storage unit;
Wherein together with the second corresponding to the selected alarm indication at step warning audio data by reproducing the generated audio signal, information indicating the broadcast range storage unit in association with alarm audio data the playback stores voice And a third step of outputting a signal to an external device .

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