JP2022055838A - Disaster prevention lighting device and disaster prevention lighting system - Google Patents

Abstract

To provide a disaster prevention lighting device capable of providing detailed inspection information.SOLUTION: A disaster prevention lighting device of an embodiment includes: a light source; a battery that supplies power to the light source during a blackout; an inspection unit that inspects at least one of the light source and the battery when receiving an inspection start instruction; and an IC tag that stores inspection information so as to be readable by wireless communication.SELECTED DRAWING: Figure 2

Description

An embodiment of the present invention relates to a disaster prevention lighting device and a disaster prevention lighting system.

The disaster prevention lighting device is a lighting device such as an emergency light or a guide light, and has a built-in light source and a battery. Normally, the battery is charged by an external power source, and in the event of a power failure, the light source is turned on by the electric power charged in the battery.

Disaster prevention lighting equipment is obliged to inspect batteries and light sources on a regular basis. Therefore, the disaster prevention lighting device is provided with an inspection unit for inspecting the life of the battery and the light source. The inspection unit is activated by an inspection switch or a remote controller. The inspection result is notified to the inspector by the monitor lamp.

Japanese Unexamined Patent Publication No. 2017-212071

Such a lighting device for disaster prevention only notifies the inspection result at the time of inspection, and only provides a simple inspection history such as the inspection result and the inspection date.

An object to be solved by the present invention is to provide a disaster prevention lighting device capable of providing inspection information.

The disaster prevention lighting device of the embodiment includes a light source, a battery that supplies electric power to the light source in the event of a power failure, an inspection unit that inspects at least one of the light source and the battery when an inspection start instruction is received, and inspection information. It includes an IC tag that can be readably stored by wireless communication.

According to the embodiment, it is possible to provide a lighting device for disaster prevention that can provide inspection information.

FIG. 1 is a perspective view schematically showing a disaster prevention lighting system according to an embodiment. FIG. 2 is a functional block diagram of the disaster prevention lighting system according to the embodiment. FIG. 3 is a functional block diagram of the IC tag and the reader / writer terminal according to the embodiment. FIG. 4 is a diagram showing an example of inspection information stored in the IC tag according to the embodiment. FIG. 5 is a functional block diagram of the composite terminal according to the modified example.

The disaster prevention lighting device (11) according to the embodiment includes a light source (27), a battery (45) that supplies electric power to the light source in the event of a power failure, and a light source (27) and a battery (45) when an inspection start instruction is received. It is provided with an inspection unit (65) to be inspected at least one of the above, and an IC tag (50) to readablely store the inspection information by wireless communication. By storing the inspection information in the IC tag (50), the inspection information can be provided later.

The disaster prevention lighting system (10) according to the embodiment includes a disaster prevention lighting device (11) and a terminal (13) capable of writing inspection information to an IC tag (50) by wireless communication. As a result, the inspection history can be written to the IC tag (50) using the terminal (13).

The inspection information includes individual identification information of the disaster prevention lighting device (11). Thereby, using the terminal (13), in addition to the inspection history, the individual identification information of the disaster prevention lighting device (11) can be written in the IC tag (50).

The terminal (13) can read the inspection information written in the IC tag (50) by wireless communication. Thereby, the inspection information written in the IC tag (50) can be easily read by using the terminal (13).

The terminal (13) can transmit inspection information. The disaster prevention lighting system (10) further includes a server (90) that receives and stores inspection information transmitted from the terminal (13). As a result, the inspection information stored in the server (90) can be used to analyze the disaster lighting device (11), for example, to predict the life of the battery or the light source.

Hereinafter, the disaster prevention lighting device and the disaster prevention lighting system according to the embodiment will be described with reference to the drawings. In the drawings, the elements indicated by the same reference numerals indicate the same elements.

FIG. 1 is a perspective view schematically showing a disaster prevention lighting system according to an embodiment. As shown in FIG. 1, the disaster prevention lighting system 10 according to the present embodiment includes a disaster prevention lighting device 11 and an operation terminal 12 capable of wirelessly communicating with the disaster prevention lighting device 11.

For example, the disaster prevention lighting device 11 is an emergency light that lights up in an emergency such as a power failure. The disaster prevention lighting device 11 is configured as an embedded type that is embedded and installed in an embedded hole opened in a ceiling plate or the like.

The disaster prevention lighting device 11 includes a light source 27, an inspection switch 33, a monitor lamp 34, a receiving unit 35, and a transmitting unit 36. The light source 27 is a light emitting element that emits illumination light. For example, the light source 27 is composed of an LED, an organic EL, or the like. The inspection switch 33 is a switch instructing the start of inspection. The monitor lamp 34 is provided with light emitting elements of a plurality of colors, and displays various states depending on the color, lighting, blinking, and the like. The receiving unit 35 and the transmitting unit 36 are for wireless communication with the operating terminal 12, the receiving unit 35 receives the wireless signal transmitted from the operating terminal 12, and the transmitting unit 36 receives the wireless signal to the operating terminal 12. Send the radio signal to be. For example, the radio signal is an infrared signal.

Further, the disaster prevention lighting device 11 includes an IC tag 50. The disaster prevention lighting system 10 includes a reader / writer terminal 13 capable of wirelessly communicating with the IC tag 50. The IC tag 50 stores the manufacturing information of the disaster prevention lighting device 11. The IC tag 50 can also store other information.

Like the operation terminal 12, the reader / writer terminal 13 is a portable terminal having a built-in battery. The reader / writer terminal 13 can write information to the IC tag 50. The reader / writer terminal 13 can also read the information stored in the IC tag 50. The reader / writer terminal 13 can further transmit information to the information server 90.

FIG. 2 is a functional block diagram of the disaster prevention lighting system according to the embodiment. As shown in FIG. 2, the disaster prevention lighting device 11 includes a battery 45, a power failure detection circuit 61, a charging circuit 62, a lighting control unit 63, a lighting circuit 64, and an inspection unit 65.

The battery 45 supplies electric power to a power source during a power failure and inspection. For example, the battery 45 is a rechargeable battery such as a Ni-Cd battery, a nickel-metal hydride battery, or a lithium-ion battery.

The power failure detection circuit 61 is a circuit for detecting a power failure. The power failure detection circuit 61 is connected to an external power source 60 such as a commercial power source. The power failure detection circuit 61 is also connected to the lighting control unit 63. When the power failure detection circuit 61 detects that the voltage of the external power supply 60 is equal to or less than a predetermined value for a predetermined time, it determines that a power failure of the external power supply 60 has occurred and gives a power failure detection signal to the lighting control unit 63.

The charging circuit 62 is a circuit for charging the battery 45. The charging circuit 62 is connected to the external power supply 60. The charging circuit 62 is also connected to the battery 45. The charging circuit 62 converts the external power supply 60 into a direct current having a predetermined voltage and supplies it to the battery 45 to charge the battery 45.

The battery 45 is connected to the lighting circuit 64. The lighting circuit 64 is a circuit that supplies electric power from the battery 45 to the light source 27 to light the light source 27 in the event of a power failure of the external power supply 60. The lighting circuit 64 is connected to the light source 27 via the lighting control unit 63.

The lighting control unit 63 is connected to the light source 27 and the monitor lamp 34. The lighting control unit 63 receives a power failure detection signal from the power failure detection circuit 61 when the external power supply 60 has a power failure, and lights the light source 27 by the lighting circuit 64 for a predetermined time or longer. Further, the lighting control unit 63 controls the lighting of the monitor lamp 34 according to the lighting state of the light source 27, the charging state of the battery 45, the inspection, the inspection result, and the like.

The inspection unit 65 is connected to the inspection switch 33, the reception unit 35, and the transmission unit 36. When the inspection switch 33 is operated, the inspection unit 65 enters the inspection mode, starts the inspection operation of the battery 45 and the light source 27, and controls the lighting control unit 63 to display the inspection result on the monitor lamp 34.

Further, the inspection unit 65 enters the inspection mode and starts the inspection operation of the battery 45 and the light source 27 based on the reception of the inspection signal and the time information from the operation terminal 12 in the reception unit 35. For example, the inspection unit 65 is composed of a microcomputer and has a processor and a storage unit 66. The storage unit 66 stores the inspection history including the inspection result and the inspection date. The storage unit 66 may also store the number of power outages, the cumulative power outage time, and the like between the previous inspection and the current inspection as an inspection history. For example, the storage unit 66 is composed of a non-volatile memory that retains the stored contents even when the power is off.

The inspection unit 65 also controls the transmission unit 36 to transmit the inspection history to the operation terminal 12. Further, the inspection unit 65 controls the reception unit 35 to transmit the inspection history from the transmission unit 36 based on the reception of the inspection history output signal from the operation terminal 12.

The operation terminal 12 is a portable terminal having a built-in battery. The operation terminal 12 has a control unit 70 that controls the operation terminal 12. A transmission unit 71, a reception unit 72, and a user interface 73 are connected to the control unit 70.

For example, the control unit 70 is composed of a microcomputer and includes a processor and a storage unit 76. The control unit 70 controls to transmit the inspection signal and the time information to the disaster prevention lighting device 11. The storage unit 76 stores the inspection history acquired from the disaster prevention lighting device 11.

The transmitting unit 71 and the receiving unit 72 are for transmitting a wireless signal to the disaster prevention lighting device 11. The transmission unit 71 transmits a radio signal received by the reception unit 35 of the disaster prevention lighting device 11. The receiving unit 72 receives the radio signal transmitted from the transmitting unit 36 of the disaster prevention lighting device 11.

The user interface 73 receives an inspection start instruction and an inspection result output instruction from the user of the operation terminal 12. The user interface 73 also displays the inspection result to the user of the operation terminal 12. For example, the user interface 73 is composed of a touch panel. Alternatively, the user interface 73 may be configured by combining a display element such as a liquid crystal panel and a switch such as a push button.

The operation terminal 12 transmits an inspection signal and time information at the time of the inspection operation, causes the disaster prevention lighting device 11 to start the inspection operation, and stores the inspection history. The operation terminal 12 also transmits an inspection history output signal at the time of inspection history output operation, and receives the inspection history from the disaster prevention lighting device 11.

Next, the operation in the disaster prevention lighting system 10 will be described.

In the disaster prevention lighting device 11, the battery 45 is charged by the charging circuit 62 in a normal time when power is supplied from the external power source 60.

In the disaster prevention lighting device 11, when the power failure detection circuit 61 detects that the power supply of the external power supply 60 has stopped at the time of a power failure when the power supply from the external power supply 60 has stopped, the lighting control unit 63 supplies the light source 27 by the power supply by the battery 45. The lighting circuit 64 is instructed to light the light, and the lighting circuit 64 lights the light source 27 by supplying electric power from the battery 45.

Further, a case where the battery 45 of the disaster prevention lighting device 11 is inspected by using the operation terminal 12 will be described.

The inspection signal and time information are transmitted from the transmission unit 71 of the operation terminal 12 by performing an inspection operation on the user interface 73 toward the disaster prevention lighting device 11 for inspecting the transmission unit 71 of the operation terminal 12.

On the other hand, when the receiving unit 35 receives the inspection signal and the time information from the operation terminal 12, the disaster prevention lighting device 11 shifts to the inspection mode and starts the inspection operation.

In the inspection operation, first, the lighting control unit 63 stops the charging of the battery 45 by the charging circuit 62. Next, the inspection unit 65 instructs the lighting control unit 63 to pass a current through the battery 45. The lighting control unit 63 receives an instruction from the inspection unit 65 and passes a current through the battery 45. At this time, it is preferable that a large current is passed through the battery 45 for about 10 seconds.

Next, the lighting control unit 63 detects the impedance of the battery 45 when a current flows. The lighting control unit 63 transmits the detected value of the impedance of the battery 45 to the inspection unit 65. The inspection unit 65 receives the detection value transmitted from the lighting control unit 63 and compares it with the threshold value stored in advance in the inspection unit 65. The inspection unit 65 determines whether the battery 45 is normal or abnormal based on the comparison result between the detected value and the threshold value. Examples of the cause of the abnormality of the battery 45 include the life of the battery 45, poor contact, and insufficient charge.

Further, the inspection of the light source 27 is performed, for example, as follows. The lighting control unit 63 turns on the light source 27 and detects the amount of emitted light from the light source 27. The lighting control unit 63 transmits the detected value of the amount of emitted light to the inspection unit 65. The inspection unit 65 receives the detection value transmitted from the lighting control unit 63 and compares it with the threshold value stored in advance in the inspection unit 65. The inspection unit 65 determines whether the light source 27 is normal or abnormal based on the comparison result between the detected value and the threshold value. The cause of the abnormality of the light source 27 is the life of the light source 27.

The inspection unit 65 instructs the lighting control unit 63 to control the lighting of the monitor lamp 34 according to the inspection result.

The inspection unit 65 stores the inspection result in the storage unit 66. The inspection unit 65 also stores the inspection date in the storage unit 66 as an inspection history associated with the inspection result based on the time information received from the operation terminal 12.

The inspection unit 65 transmits the inspection history stored in the storage unit 66 from the transmission unit 36. The inspection history may be automatically transmitted after the inspection history is stored, or may be transmitted after receiving the inspection history output signal from the operation terminal 12.

After the inspection operation is completed, the inspection unit 65 instructs the lighting control unit 63 to restart the charging of the battery 45 by the charging circuit 62. The charging circuit 62 resumes charging the battery 45.

On the other hand, when the receiving unit 72 receives the inspection history from the disaster prevention lighting device 11, the operation terminal 12 stores the inspection history in the storage unit 76 and displays the inspection result on the user interface 73.

The inspection result can be confirmed by either the monitor lamp 34 of the disaster prevention lighting device 11 or the operation terminal 12. If the battery 45 or the light source 27 is determined to be abnormal by the inspection, appropriate measures will be taken. For example, if the battery 45 or the light source 27 has reached the end of its life, it will be replaced on the spot or at a later date.

After that, the inspection history is written in the IC tag 50 using the reader / writer terminal 13. The inspection history includes inspection dates and inspection results. The inspection history may also include the number of power outages, the cumulative power outage time, and the like between the previous inspection and the current inspection. The inspection history is additionally written for each inspection.

Further, in addition to the inspection history, other information such as individual identification information of the disaster prevention lighting device 11 and replacement history of parts may be written in the IC tag 50 using the reader / writer terminal 13.

For example, the individual identification information is the installation location of the disaster prevention lighting device 11. Of course, the individual identification information may be other information that can identify the disaster prevention lighting device 11. Since the individual identification information does not need to be updated, it only needs to be written once at the beginning.

For example, the replacement history may be the type of the replaced part, for example, the battery 45 or the light source 27, and the replacement date. The replacement history is additionally written when the part is replaced.

Further, the information stored in the IC tag 50 is read by using the reader / writer terminal 13 and transmitted to the server 90.

Subsequently, the operation of writing and reading information by the reader / writer terminal 13 for the IC tag 50 will be described with reference to FIG. FIG. 3 is a functional block diagram of the IC tag 50 and the reader / writer terminal 13 shown in FIG.

The reader / writer terminal 13 includes a user interface 81, a processing unit 82, a storage medium 83, an antenna 84, and a transmission unit 85.

The user interface 81 receives instructions and information input from the user of the reader / writer terminal 13. The user interface 81 also provides information to the user of the reader / writer terminal 13 by display or voice. For example, the user interface 81 is composed of a touch panel. Alternatively, the user interface 81 may be configured by combining a display element such as a liquid crystal panel and a switch such as a push button.

The processing unit 82 controls the entire user interface 81, the storage medium 83, and the transmission unit 85. For example, the processing unit 82 receives instructions and information from the user interface 81, supplies read and write instructions to the antenna 84, extracts inspection history from the received signal by the antenna 84, individual identification information, and exchange history, and a storage medium. It supplies the stored information to the 83 and the transmission information to the transmission unit 85.

The processing unit 82 includes a processor. The processor includes any one of a CPU (Central Processing Unit), an ASIC (Application Specific Integrated Circuit), an FPGA (Field Programmable Gate Array), a DSP (Digital Signal processor) and the like. The storage medium 83 may include an auxiliary storage device in addition to the main storage device. For example, the storage medium 83 is a semiconductor memory. The processor of the processing unit 82 performs various processes by executing a program stored in the storage medium 83.

The antenna 84 transmits the read instruction and the write instruction supplied from the processing unit 82 as radio waves. The antenna 84 also receives the radio wave transmitted from the IC tag 50 and supplies the received signal to the processing unit 82.

The storage medium 83 stores the stored information supplied from the processing unit 82. The stored information is information input to the user interface 81 by the user of the reader / writer terminal 13 and information read from the IC tag 50.

The transmission unit 85 transmits the information of the storage medium 83 supplied from the processing unit 82 as radio waves. For example, the transmission information is manufacturing information, inspection history, individual identification information, and exchange history. The transmission information is received by the server 90.

The IC tag 50 includes a storage medium 51, a processing unit 52, and an antenna 53.

The IC tag 50 stores the manufacturing information of the disaster prevention lighting device 11. For example, the manufacturing information has a model name, a lot number, and a manufacturing location. Manufacturing information is not rewritable. The storage medium 51 can also store the information supplied from the processing unit 52.

For example, the storage medium 51 of the IC tag 50 is composed of a semiconductor memory like the storage medium 83 of the reader / writer terminal 13.

The antenna 53 receives the radio wave transmitted from the reader / writer terminal 13 to generate electric power, and supplies the generated electric power to the processing unit 52. The antenna 53 also transmits the information supplied from the processing unit 52 as radio waves.

The processing unit 52 operates by receiving the electric power generated by the antenna 53. When the antenna 53 receives the radio wave of the reading instruction, the processing unit 52 reads the stored information of the storage medium 51 and supplies it to the antenna 53. When the antenna 53 receives the radio wave of the writing instruction, the processing unit 52 extracts information from the received signal and supplies it to the storage medium 51.

The processing unit 52 of the IC tag 50 includes a processor, similarly to the processing unit 82 of the reader / writer terminal 13. The processor of the processing unit 52 is configured in the same manner as the processor of the processing unit 82. The processor of the processing unit 52 performs processing by executing a program stored in the storage medium 51.

As described above, after the inspection is completed, the user uses the reader / writer terminal 13 to transmit the transmission information to the IC tag 50. The transmitted information includes the inspection history. The transmitted information also includes individual identification information of the disaster prevention lighting device 11 and a replacement history of parts, if necessary.

The transmission information is stored in the storage medium 83 by an input operation to the user interface 81. Further, when the transmission instruction is input to the user interface 81, the reader / writer terminal 13 transmits the radio wave of the writing instruction from the antenna 84.

The IC tag 50 that has received the radio wave of the writing instruction extracts transmission information from the radio wave of the writing instruction and stores it in the storage medium 51. As a result, in addition to the manufacturing information of the disaster prevention lighting device 11, the individual identification information is written in the IC tag 50 when necessary, the inspection history is written at the time of inspection, and the replacement history is written at the time of parts replacement.

The inspection history is written every time the inspection is performed, while the individual identification information and the exchange history are written when necessary. Hereinafter, for convenience, the writing of the inspection history including the writing of the individual identification information and the exchange history will be referred to.

FIG. 4 is a diagram showing an example of stored information of the IC tag 50. As shown in FIG. 4, the stored information of the IC tag 50 includes the manufacturing information of the disaster prevention lighting device 11, the individual identification information, and the inspection history. For example, the manufacturing information is the model name and lot number of the disaster prevention lighting device 11. For example, the individual identification information is the installation location. For example, the installation location is information such as a corridor, a lobby, or a window. The individual identification information is not limited to the installation location, and may be other information. Since the individual identification information does not need to be updated, it only needs to be written once at the beginning. For example, the inspection history is an inspection result and an inspection date. The inspection history may also include the number of power outages, the cumulative power outage time, and the like between the previous inspection and the current inspection. The inspection history is additionally written for each inspection.

After writing the inspection history, the user uses the reader / writer terminal 13 to read the stored information of the IC tag 50 from the IC tag 50. The stored information of the IC tag 50 includes manufacturing information and individual identification information of the disaster prevention lighting device 11, inspection history at the time of past inspection, and replacement history at the time of parts replacement.

The stored information of the IC tag 50 is read by the user of the reader / writer terminal 13 by inputting a reading instruction to the user interface 81. When the reading instruction is input to the reader / writer terminal 13, the reader / writer terminal 13 transmits the radio wave of the reading instruction from the antenna 84.

The IC tag 50 that has received the radio wave of the reading instruction reads the stored information from the storage medium 51 and transmits it as a radio wave.

The reader / writer terminal 13 that has received the radio wave from the IC tag 50 extracts the stored information from the received signal. The reader / writer terminal 13 displays the stored information of the extracted IC tag 50 on the user interface 81. The reader / writer terminal 13 also stores the stored information of the extracted IC tag 50 in the storage medium 83 as storage information.

The reader / writer terminal 13 also transmits the storage information of the storage medium 83 to the server 90. The storage information of the storage medium 83 is transmitted by the user of the reader / writer terminal 13 inputting a transmission instruction to the user interface 81. When the transmission instruction is input to the reader / writer terminal 13, the reader / writer terminal 13 reads out the stored information of the storage medium 83 and transmits it from the transmission unit 85.

For example, information is transmitted from the reader / writer terminal 13 every time the disaster prevention lighting device 11 is inspected. When inspecting a plurality of disaster prevention lighting devices 11, information may be transmitted after the inspection of the plurality of disaster prevention lighting devices 11 is completed.

When the server 90 receives the information transmitted from the reader / writer terminal 13, the server 90 stores the received information in the database 91. As a result, information such as manufacturing information and individual identification information of the disaster prevention lighting device 11, inspection history at the time of past inspection, replacement history at the time of parts replacement, and the like are accumulated in the database 91.

The information stored in the database 91 is read out when necessary by a supplier, a manufacturer, or the like, and is used for analysis of the disaster prevention lighting device 11. For example, the stored information in the database 91 can be used for grasping the tendency of failure of the disaster prevention lighting device 11, predicting the life of the battery 45 and the light source 27, discovering other vulnerabilities, estimating the replacement time, and the like. It is used to relate to the installation location.

The server 90 may have a function of analyzing the information stored in the database 91. Further, the server 90 may have a function of transmitting the analysis result to the supplier, the manufacturer, or the like of the disaster prevention lighting device 11.

The disaster prevention lighting device 11 according to this embodiment includes an IC tag 50. The IC tag 50 stores the manufacturing information of the disaster prevention lighting device 11 in advance. The IC tag 50 can also store the inspection history. In addition to the inspection history, the IC tag 50 can further store other information, for example, inspection information including individual identification information of the disaster prevention lighting device 11, replacement history of parts, and the like. The stored information of the IC tag 50 can be read by wireless communication.

This makes it possible to save detailed inspection information that is not limited to the inspection history. Further, even if the information stored in the storage unit 66 of the inspection unit 65 of the disaster prevention lighting device 11 is lost due to some trouble, the reader / writer terminal 13 acquires the necessary information from the IC tag 50. It is possible to do.

In the disaster prevention lighting system 10 of the present embodiment, the manufacturing information of the disaster prevention lighting device 11 is stored in the IC tag 50 in advance. The inspection history is stored in the IC tag 50 each time an inspection is performed. Further, if necessary, the individual identification information of the disaster prevention lighting device 11 and the replacement history of parts are stored in the IC tag 50. The stored information of the IC tag 50, that is, the manufacturing information and inspection history of the disaster prevention lighting device 11, the individual identification information, the replacement history of parts, and the like are read by the reader / writer terminal 13 by wireless communication. As a result, the user of the reader / writer terminal 13 can easily acquire the manufacturing information and the inspection information of the disaster prevention lighting device 11.

Further, the reader / writer terminal 13 can transmit the information read from the IC tag 50, and the transmission information is stored in the database 91 of the server 90. When the storage capacity of the storage unit 66 of the inspection unit of the disaster prevention lighting device 11 is small, or when the storage capacity of the storage medium 51 of the IC tag 50 is small, it is difficult to store the inspection information of a large number of inspections.

By accumulating the information read from the IC tag 50 in the database 91 of the server 90, it becomes possible to collate the inspection information of a large number of inspections. In addition, it becomes possible to collate the inspection information of the inspection of a large number of disaster prevention lighting devices 11. Further, it becomes possible to collate the inspection information of a large number of inspections of a large number of disaster prevention lighting devices 11.

Further, the inspection information stored in the database 91 can be used to analyze the disaster prevention lighting device 11.

In the present embodiment, a reader / writer terminal 13 capable of both writing and reading has been described as an example of a terminal capable of wireless communication with the IC tag 50, but the reader / writer terminal 13 is a writer terminal capable of only writing. It may be replaced with a reader terminal that can only read.

Next, with reference to FIG. 5, the composite terminal according to the modified example will be described. FIG. 5 is a functional block diagram of the composite terminal according to the modified example. In FIG. 5, the members having the same reference numerals as those shown in FIGS. 2 and 3 are similar members, and detailed description thereof will be omitted. In the following, the differences will be emphasized.

As shown in FIG. 5, the composite terminal 14 according to this modification is a portable terminal having a built-in battery, like the operation terminal 12 and the reader / writer terminal 13. Like the operation terminal 12, the composite terminal 14 includes a control unit 70, a transmission unit 71, and a reception unit 72. The configurations and functions of the control unit 70, the transmission unit 71, and the reception unit 72 of the composite terminal 14 are the same as those of the control unit 70, the transmission unit 71, and the reception unit 72 of the operation terminal 12 shown in FIG.

Similar to the reader / writer terminal 13, the composite terminal 14 also includes a processing unit 82, a storage medium 83, an antenna 84, and a transmission unit 85. The configuration and functions of the processing unit 82, the storage medium 83, the antenna 84, and the transmitting unit 85 of the composite terminal 14 include the processing unit 82, the storage medium 83, the antenna 84, and the transmitting unit 85 of the reader / writer terminal 13 shown in FIG. The same is true.

The composite terminal 14 also comprises a user interface 86. The user interface 86 is connected to the control unit 70 and the processing unit 82, and exchanges instructions and information between the control unit 70 and the processing unit 82. The configuration and functions of the user interface 86 are the same as those of the user interface 73 of the operation terminal 12 shown in FIG. 2 and the user interface 81 of the reader / writer terminal 13 shown in FIG.

The composite terminal 14 has the function of the operation terminal 12 shown in FIG. 2 and the function of the reader / writer terminal 13 shown in FIG. 3 in common. That is, the interaction between the composite terminal 14 and the disaster prevention lighting device 11 and the interaction between the composite terminal 14 and the IC tag 50 are as described above.

Since the composite terminal 14 has both the function of the operation terminal 12 and the function of the reader / writer terminal 13, the operability is excellent as compared with the case where the operation terminal 12 and the reader / writer terminal 13 are individually operated. For example, by providing the information read from the disaster prevention lighting device 11 to the storage unit 76 of the control unit 70 to the processing unit 82, it is possible to significantly save the trouble of inputting the information by the user of the composite terminal 14. ..

In the embodiment, the IC tag 50 has been described as a passive type having no built-in battery, but may be an active type having a built-in battery.

Further, although an example of storing the manufacturing information in the IC tag 50 has been described, the target for storing the manufacturing information is not limited to this, and other electronic tags, for example, RF tags may be used.

The emergency light has been described as an example of the disaster prevention lighting device 11, but the disaster prevention lighting device 11 is not limited to this, and the disaster prevention lighting device 11 may be a lighting device such as a guide light that lights a light source using a battery as a power source in an emergency. good.

Although some embodiments of the present invention have been described, these embodiments or examples are presented as examples and are not intended to limit the scope of the invention. These embodiments or examples can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments or examples and variations thereof are included in the scope and gist of the invention, and are included in the scope of the invention described in the claims and the equivalent scope thereof.

10 ... Disaster prevention lighting system, 11 ... Disaster prevention lighting device, 12 ... Operation terminal, 13 ... Reader / writer terminal, 14 ... Composite terminal, 27 ... Light source, 33 ... Inspection switch, 34 ... Monitor lamp, 35 ... Receiver, 36 ... Transmission unit, 45 ... Battery, 50 ... IC tag, 51 ... Storage medium, 52 ... Processing unit, 53 ... Antenna, 60 ... External power supply, 61 ... Power failure detection circuit, 62 ... Charging circuit, 63 ... Lighting control unit, 64 ... lighting circuit, 65 ... inspection unit, 66 ... storage unit, 70 ... control unit, 71 ... transmission unit, 72 ... reception unit, 73 ... user interface, 76 ... storage unit, 81 ... user interface, 82 ... processing unit, 83. ... storage medium, 84 ... antenna, 85 ... transmitter, 86 ... user interface, 90 ... server, 91 ... database.

Claims (5)

With a light source;
With a battery that powers the light source in the event of a power outage;
With the inspection unit to inspect at least one of the light source and the battery when receiving an inspection start instruction;
With an IC tag that readablely stores inspection information via wireless communication;
Lighting equipment for disaster prevention equipped with. With the disaster prevention lighting device according to claim 1;
With a terminal that can write the inspection information to the IC tag by wireless communication;
Lighting system for disaster prevention equipped with. The inspection information includes individual identification information of the disaster prevention lighting device.
The lighting system for disaster prevention according to claim 2. The terminal can read the inspection information written in the IC tag by wireless communication.
The lighting system for disaster prevention according to claim 2 or 3. The terminal can transmit the inspection information, and the terminal can transmit the inspection information.
Further comprising a server for receiving and storing the inspection information transmitted from the terminal.
The lighting system for disaster prevention according to claim 4.

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