JPWO2009004993A1 - Alarm device - Google Patents

Abstract

An alarm device according to the present invention operates based on an abnormality detection signal and starts boosting a supplied voltage, charge storing means for storing charges supplied from the boost circuit, and the charge storing means And a light emitting portion that emits light using the electric charge accumulated in the.

Description

  The present invention relates to an alarm device.

In electrical appliances, an alarm is given to notify the abnormal state of the device by sound or light.
JP 2002-340472 A

  However, in the alarm using only sound, the alarm sound is canceled by ambient noise, and the alarm may be missed. For this reason, a means for visually appealing using light is used, but the light of a normal flashing lamp is often overlooked by the surrounding light.

  In view of the above, an object of the present invention is to provide an alarm device that issues an alarm that a user does not overlook.

  In order to achieve the above object, an alarm device according to the present invention operates based on an abnormality detection signal and starts boosting a supplied voltage, and charge storage for storing charge supplied from the booster circuit And a light emitting unit that emits light using the charge accumulated in the charge accumulating means.

  The alarm device and the alarm system according to the present invention can have various configurations other than the above, and these configurations will be described in detail below.

  ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to provide the alarm device which issues the alarm which a user does not overlook.

These are block diagrams which show the apparatus provided with the alarm device concerning embodiment of this invention. These show the detail of the light emission part driver 34 of FIG. 1, and concern on embodiment which a light emission part is LED. These show the detail of the light emission part driver 34 of FIG. 1, and are related to embodiment which a light emission part is a xenon tube. These are figures which show the external appearance of a refrigerator. These are block diagrams which show the whole household where the refrigerator was installed. FIG. 6 is a block diagram showing details of the alarm unit 164 shown in FIG. 5. These are the flowcharts for explaining the details of step S1 in FIG. 7 and for explaining the guidance when installing the refrigerator in detail. These are the flowcharts for explaining the details of step S1 in FIG. 7 and for explaining the guidance when installing the refrigerator in detail. These are the flowcharts for demonstrating the detail of the alarm procedure in case the door of a refrigerator is open in connection with 1st Example of this invention. These are the flowcharts which show in detail the calculation of the integrated fee in step S52 of FIG. These are the flowcharts which show the detailed procedure of the alarm light emission of step S84 of FIG. These are the flowcharts which show the detail of the instruction | indication to the alarm unit shown to FIG.9 S86. These are the flowcharts for describing the detail at the time of the alarm stop button of a refrigerator being pushed. These are the flowcharts which show the process by the side of the refrigerator in detail, when an alarm stop packet is transmitted from the fluorescent lamp provided with an alarm device with respect to a refrigerator, or another alarm unit. These are the flowcharts which show in detail the processing of the alarm unit when the alarm unit is installed in the outlet. These are the flowcharts showing the details when the alarm stop button is pressed on the alarm unit side. These are flowcharts showing details when a unit alarm stop packet is received on the unit side. These are related to the second embodiment of the present invention and are flowcharts for explaining in detail the procedure of alarm processing when the power of the refrigerator is not supplied. FIG. 19 is a flowchart for explaining in detail a procedure for holding parameters used for calculating a light amount attenuation rate in step S194 in FIG. 18; These are the flowcharts for demonstrating in detail the procedure which calculates the light quantity attenuation factor of step S194 of FIG. These are the flowcharts for demonstrating in detail the procedure for calculating the time when the power was not supplied. These are the flowcharts for demonstrating in detail the power failure light emission of step S198 of FIG. These are related to the third embodiment of the present invention, and are flowcharts for explaining in detail the procedure of alarm processing when the power of the refrigerator is not supplied. Is related to the fourth embodiment of the present invention, and describes in detail the procedure of performing alarm light emission and sounding alarm simultaneously after a certain period of time has elapsed since the refrigerator door was opened, and repeating these alarms. Is related to the fifth embodiment of the present invention, and describes in detail the procedure for issuing a sounding alarm after alarm light emission after a lapse of a certain period of time after the refrigerator door is opened and repeating these alarms. These are the flowcharts for demonstrating the detail of the process by the side of the alarm unit corresponding to the flowchart of 4th Example and 5th Example described by FIG. 24 and FIG. These relate to the sixth embodiment of the present invention. These are the flowcharts for demonstrating the detail of the process by the side of the alarm unit corresponding to 6th Example of this invention described in FIG. These relate to the seventh embodiment of the present invention, and determine the timing of light emission by measuring the charge amount of the capacitor provided in the light emitting section. These relate to the eighth embodiment of the present invention. These relate to the ninth embodiment of the present invention. These relate to the tenth embodiment of the present invention. These relate to the eleventh embodiment of the present invention. These relate to the twelfth embodiment of the present invention. These relate to the thirteenth embodiment of the present invention. FIG. 36 is a flowchart showing details of alarm pattern 1 shown in step S462 of FIG. FIG. 36 is a flowchart showing details of alarm pattern 2 shown in step S464 of FIG. These relate to the fourteenth embodiment of the present invention. These relate to the fifteenth embodiment of the present invention. These are related to the sixteenth embodiment of the present invention and are a flowchart showing step S554 of FIG. 39 in detail. These relate to the seventeenth embodiment of the present invention, and are obtained by adding step S582 to FIG.

Explanation of symbols

2 Distribution board 4 Refrigerator 34 Light emitting unit driver 60 Fluorescent lamp

  FIG. 1 is a block diagram showing an apparatus provided with an alarm device according to an embodiment of the present invention. In the figure, a refrigerator 4 provided with an alarm device and a fluorescent lamp 60 are connected to a distribution board 2.

  The refrigerator 4 includes a power source 6, a demultiplexing / synthesis module 8, a compressor 10, a freezer compartment 12, a refrigerator compartment 14, a microcomputer 16, a freezer compartment temperature detection sensor 18, a refrigerator compartment temperature detection sensor 20, a battery 22, a wireless transmission / reception unit 24, Operation unit 26, display unit 28, first light emitting unit 30, second light emitting unit 32, emergency power source 33, light emitting unit driver 34, audio decoder 36, DAC (digital analog converter) 38, speaker amplifier 40, speaker 42, microphone 44, an ADC (analog / digital converter) 46, an audio encoder 48, an ambient temperature measurement sensor 50, a door opening / closing sensor 52, an alarm stop button 54, a human sensor 56, an illuminance sensor 58, and an infrared sensor 59.

  A detailed description of the refrigerator 4 will be described. A power supply 6 provided in the refrigerator 4 supplies power to the demultiplexing / synthesis module 8. The demultiplexing / synthesis module 8 plays a role for transmitting and receiving a PLC (Power Line Communication) signal in which a signal is superimposed on electric power. The electric power supplied from the power supply 6 supplies electric power to the compressor 10 via the demultiplexing / combining module 8 and the like, and the compressor 10 cools the freezer compartment 12 and the refrigerator compartment 14. The microcomputer 16 includes an arithmetic processing unit and a volatile / nonvolatile storage device, and receives output from the freezer compartment temperature detection sensor 18 and the refrigerator compartment temperature detection sensor 20. The microcomputer 16 transmits instructions to other components of the refrigerator 4 and receives signals from the components. The battery 22 supplies power to the microcomputer 16. The wireless transmission / reception unit 24 transmits data received from the outside to the microcomputer 16 or transmits data received from the microcomputer 16 to the outside. The operation unit 26 includes buttons that accept an operation from the user, and transmits the accepted operation to the microcomputer 16. The display unit 28 displays the state of the refrigerator 4 and the like under the control of the microcomputer 16. The first light emitting unit 30 and the second light emitting unit 32 issue a warning by light emission in order to appeal to the user's vision. Two types of light emitting parts are mounted, which emit light by flashing light when the electric charge accumulated in the capacitor flows into the light emitting part, and light emitted by supplying current to the LED. Since this flash emission is very effective when warning is performed, flash emission is performed when warning. The direction of these light emitting units can be adjusted automatically or manually. The emergency power supply 33 is for supplying power to the first light emitting unit 30 and the second light emitting unit 32 even when power is not supplied to the refrigerator in the event of an emergency such as a power failure. The emergency power source 33 may be a built-in storage battery or a battery replaceable from the outside. In response to an instruction from the microcomputer 16, the light emitting unit driver 34 drives the first light emitting unit 30 and the second light emitting unit 32. The audio decoder 36 decodes the audio data received from the microcomputer 16 and transmits the decoded digital data to the DAC 38. The DAC 38 converts the received digital data into analog data and transmits the analog data to the speaker amplifier 40, and sounds and electronic sounds amplified by the speaker 42 are generated. The microphone 44 collects sound from the outside and transmits it to the ADC 46, which converts the analog data into digital data and transmits it to the sound encoder 48. The microphone 44 is used, for example, when an instruction from the user to the refrigerator is given by the user's voice or for measuring the noise level around the refrigerator. The audio encoder 48 performs a process of compressing the digital data, and the compressed digital data is recorded in the microcomputer 16. The ambient temperature sensor 50 measures the temperature outside the refrigerator and transmits it to the microcomputer 16. The door opening / closing sensor 52 detects whether the door of the refrigerator 4 is open, and the detection result is transmitted to the microcomputer 16. The alarm stop button 54 is a button for the user to stop an alarm issued from the refrigerator, and transmits to the microcomputer 16 whether or not the button has been pressed. The interpersonal sensor 56 measures whether or not there is a person around the refrigerator, and transmits the measurement result to the microcomputer 16. The illuminance sensor 58 is for measuring the amount of light outside the refrigerator, and transmits the measured amount of light to the microcomputer 16. The infrared sensor 59 is used when remotely controlling the refrigerator. In that case, a television remote controller may be used or a dedicated remote controller may be provided.

  In addition to the refrigerator 4, a fluorescent lamp 60 is also connected to the distribution board 2. The fluorescent lamp 60 includes a power source 62, a demultiplexing / synthesis module 64, a fluorescent unit 66, a microcomputer 67, a light emitting unit driver 68, and a third light emitting unit 70. The power source 62 receives power supplied from the distribution board 2 and supplies power to the fluorescent unit 66 via the branching / synthesizing module 64. Further, the demultiplexing / synthesis module 64 transmits the PLC signal to the microcomputer 67, and the microcomputer 67 transmits information including the timing of light emission to the light emitting unit driver 68, and the light emitting unit driver 68 drives the third light emitting unit 70. The third light emitting unit 70 is a type of light emitting means for flashing the amount of light in a short time using charges from a charge storage means such as a capacitor.

  Although detailed operation will be described later, when the door of the refrigerator 4 is left open, the microcomputer 16 determines that the refrigerator 4 is abnormal, and the first light emitting unit 30 and the second light emitting unit 32 emit light. Then, a signal indicating that an abnormality has occurred in the refrigerator 4 is transmitted to the fluorescent lamp 60 by the PLC signal. When the fluorescent lamp 60 receives an abnormal signal from the refrigerator 4, the third light emitting unit 70 emits light. Thereby, even when there is no user near the refrigerator 4, the abnormality of the refrigerator 4 can be recognized. Usually, since the fluorescent lamp 60 is provided on the ceiling surface of the room, the light from the third light emitting unit 70 provided in the fluorescent lamp 60 illuminates the entire room.

  FIG. 2 shows details of the light emitting unit driver 34 of FIG. 1, and relates to an embodiment in which the light emitting units 30 and 32 are LEDs. The LED driver control circuit 80 receives a light emission preparation command from the microcomputer 16 to the light emitting unit driver 34. The light emission preparation may be performed at the same time as the power of the refrigerator 4 is turned on. In the light emission preparation stage, a signal for driving the charge pump circuit 82 is transmitted from the LED driver control circuit 80, and the charge pump circuit 82 receiving the signal charges the capacitor 84. When the capacitor 84 reaches a certain amount of charge, the light emission preparation is completed. When a light emission command is issued from the microcomputer 16 to the light emitting unit driver 34, the LED driver control circuit 80 turns on the switch 86 and flows the charge accumulated in the capacitor 84 into the LED 88 as a current. The constant current source 90 is used to adjust the amount of current, and its current driving capability is variable.

  FIG. 3 shows details of the light emitting unit driver 34 of FIG. 1, and relates to an embodiment in which the light emitting units 30 and 32 are xenon tubes. The xenon tube driver control circuit 100 receives a light emission preparation command from the microcomputer 16 to the light emitting unit driver 34. In the light emission preparation stage, a signal for driving the charge pump circuit 102 is transmitted from the xenon tube driver control circuit 100 and the capacitor 110 is charged. When the charged charge reaches a certain amount, the light emission preparation is completed. When a light emission command is issued from the microcomputer 16 to the light emitting unit driver 34, the xenon tube driver control circuit 100 drives the transistor 104 to flow current to the primary coil 106. Then, a high voltage is generated in the secondary coil 108 by the transformation action. The xenon tube 114 is in an induced state when a high voltage is applied. When the charge accumulated in the capacitor 110 is supplied to the xenon tube 114 as a current by driving the transistor 112, the xenon tube 114 emits light. A xenon tube can pass a current about 100 times that of an LED, and the amount of emitted light is also larger than that of an LED. Note that the xenon tube driver control circuit 100 may measure the amount of charge of the capacitor 110, and perform control so that the xenon tube emits light when the accumulated amount of charge reaches a certain amount.

  FIG. 4 is a view showing the appearance of the refrigerator. The 1st light emission part light emission part 30 is provided in the upper surface of the refrigerator 4, a right surface, or a front, and the 2nd light emission part 32 is provided in the door or refrigerator of a refrigerator. For any one of the first light emitting unit 30 and the second light emitting unit 32, at least a light emitting unit that performs flash light emission is used.

  FIG. 5 is a block diagram showing the entire home where the refrigerator is installed. In the home 150, electric power is supplied from the distribution board 152 via the electric lamp line 154. Electric power from the power line 154 to the room 156 is supplied via the outlet 158. The refrigerator 4 is connected to the outlet 158. In addition, power from the power line 154 to the room 160 is supplied via the outlet 162. An alarm unit 164 is connected to the outlet 162. Details of the alarm unit 164 will be described later. In addition, power from the power line 154 to the room 166 is supplied via the outlet 168. Similarly, power from the power line 154 to the room 170 is also performed through the outlet 172, and power from the power line 154 to the room 174 is also performed through the outlet 176.

  FIG. 6 is a block diagram showing details of the alarm unit 164 shown in FIG. The alarm unit 164 includes a plug 200, a power supply unit 202, an emergency storage battery 204, a demultiplexing / synthesis module 206, a microcomputer 208, a wireless transmission / reception unit 210, an audio decoder 212, a DAC 214, a speaker amplifier 216, a speaker 218, an alarm display unit 220, The light emitting unit driver 222, the light emitting unit 224, an alarm stop button 225, and a power display unit 226 are configured.

  The alarm unit 164 receives power supply from the plug 200. The power unit 202 converts the power into appropriate power for driving the alarm unit. The power supply unit 202 is provided with an emergency storage battery 204 that operates in place of the power supply unit 202 in an emergency. The power supply unit 202 supplies the power to the demultiplexing / combining module 206, and the demultiplexing / combining module 206 separates the power and the PLC signal. The demultiplexing / synthesis module 206 supplies power and a PCL signal to the microcomputer 208. The wireless transmission / reception unit 210 transmits a transmission signal from the microcomputer 208 to the outside, or receives a signal transmitted from the outside and transmits the signal to the microcomputer 208. The audio decoder 212 decodes the digital data transmitted from the microcomputer 208 and transmits it to the DAC 214. The DAC 214 converts digital data into an analog signal and transmits the analog signal to the speaker amplifier 216, and the speaker 218 is driven by the amplified audio signal. The alarm display unit 220 displays the alarm signal received from the microcomputer 208 as text data. The light emitting unit driver 222 receives the light emission command signal from the microcomputer 208 and drives the light emitting unit 224. The alarm stop button 225 transmits an alarm stop command to the microcomputer 208 in response to a user button operation. The power display unit 226 displays whether power is supplied to the alarm unit 164.

  FIG. 7 is a basic chart showing the basic operation of the refrigerator 4 of the present invention. When the refrigerator 4 is turned on, the refrigerator facility processing guidance is performed in step S1, and then normal cooling is performed in step S2. In step S3, it is always monitored whether an interruption process occurs during cooling. Unless the interruption process occurs, the normal cooling returning to step S2 is repeated. When interrupt processing occurs, processing corresponding to the interrupt processing is performed in step S4.

  FIG. 8 describes the details of step S1 in FIG. 7, and is a flowchart for explaining in detail the guidance when installing the refrigerator 4. When the power is turned on in FIG. 7, the initial announcement in step S5 in FIG. 8 starts. Then, in step S6, a test warning sound is sounded, and in step S8, a question is made as to whether or not the test warning volume is to be a future warning volume. If there is a response from the user to the question in step S10, it is determined whether the response from the user responds when the test alarm volume is set to the future alarm volume or a response to change the volume in step S12. Is made. If it is confirmed in step S12 that the test alarm volume is not set to the future alarm volume, the test alarm volume is adjusted in step S14, and the process returns to step S6 to set the test alarm volume again. If a user response confirming that the test alarm volume is to be the future alarm volume is confirmed in step S12, the test alarm volume is set to the alarm sound volume in step S16, and the process proceeds to step S18. If it is determined in step S10 that there is no response operation from the user, the volume of the alarm sound is automatically set and the process proceeds to step S18. In addition, although the response of the user here is performed by the operation unit 26 provided in the refrigerator 4, it is preferable to set the volume of the refrigerator 4 in a remote place in a test assuming an actual use environment. A voice response is also possible. In addition, an infrared communication unit included in the TV remote control may be used. For example, the volume adjustment button on the TV remote control may be used to adjust the test alarm volume.

  In step S18, a test warning light emission announcement is made. Then, in step S22, a test warning light emission is performed, and in step S24, a question is made as to whether or not the test warning light emission amount is set as a future warning light emission amount. If there is a response operation from the user in step S26, it is determined in step S28 whether or not the user operation has agreed to set the test warning light emission amount as the future warning light emission amount. If not agreed, the test warning light emission amount is increased in step S30 and the process returns to step S22. If it is determined in step S28 that the test warning light emission amount is the future warning light emission amount, the test warning light emission amount is set to the alarm light emission amount in step S32, and the flowchart is ended. If it is determined in step S26 that there is no response operation from the user, the warning light emission amount is automatically set in step S34 and the flowchart is ended.

  FIG. 9 relates to the first embodiment of the present invention, and shows in detail a warning procedure when the door of the refrigerator 4 is open. The flowchart of FIG. 9 starts when it is detected that the door of the refrigerator 4 is open. In step S42, the door open flag is turned on, and the temperature in the cabinet when the door is opened is maintained in step S44. This temperature is stored as the temperature inside the door when the door is opened. In step S46, a fixed time is counted, and in step S48, it is determined whether the count time has reached a fixed value. If the count time does not reach a certain value, it is determined in step S50 whether the door is open. If it is determined that the door is open, the process returns to step S48, and the door is not open in step S50. If it is determined that, the door opening flag is turned off and the accumulated charge is displayed. This accumulated charge is calculated based on the power consumption generated extra by opening the door, compared to when the door is kept closed. Details of the calculation method of the accumulated fee will be described later. If it is determined in step S48 that the count time has reached a constant, it is determined in step S54 whether the interpersonal sensor 56 is on. The interpersonal sensor 56 is provided in order to delay the alarm start time when there is a person around the refrigerator 4. If it is determined in step S54 that the interpersonal sensor 56 is turned on, a predetermined time is started in step S56. Then, the counter 58 determines whether or not the count time has reached a constant value. If it is determined that the counter time has not reached, it is determined in step S60 whether or not the door is open, and the door is closed. If it is determined, the door opening flag is turned off in step S62, the accumulated charge is displayed, and the flowchart ends.

  If it is determined in step S60 that the door is open, the process returns to step S58. If it is determined in step S58 that the count time has reached a constant value, the process proceeds to step S64, which is the same as in the case where it is determined in step S54 that the interpersonal sensor 56 is off. In step S64, the temperature difference between the ambient temperature and the temperature in the cabinet when the door is open is detected, and in step S66, the temperature difference table is referred to, the time until the alarm is started is determined, and the counting of a predetermined time is started. For example, since there is not much difference between the temperature in the refrigerator compartment in the midwinter and the temperature around the refrigerator, there is no need to issue an alarm immediately. That is, this temperature difference table pursues the directivity between the refrigerator and the external environment. In step S66, the count time is determined with reference to the temperature difference table, and after the count is started, it is determined in step S68 whether the count time has elapsed. If the count time has not reached a certain value, it is determined in step S70 whether or not the door is open. If it is determined that the door is closed, the door open flag is turned off in step S72 and the accumulated fee is charged. Is displayed and the flowchart is terminated. If it is determined in step S70 that the door is open, the process returns to step S68. If it is determined in step S68 that the count time has reached a fixed value, a sound generation alarm is sounded in step S74. This sounding warning is a warning by voice or electronic sound, and sounding is repeated for a predetermined time in step S74.

  After a sound generation alarm is generated in step S74, counting for a certain time starts in step S76. In step S78, a determination is made as to whether the count time has reached a constant value. If it is determined that the count time has not reached a fixed value, a determination is made in step S80 as to whether the door is open. If it is determined that the door is closed, the door opening flag is turned off in step S82, the accumulated charge is displayed, and the flowchart is terminated. If it is determined in step S80 that the door is open, the process returns to step S78. If it is determined in step S78 that the count time has reached a constant, a warning light emission process is performed in step S84. The details of this warning light emission process will be described later. In step S86, an alarm instruction is issued to the alarm unit 164. Details of the warning instruction to the warning unit 164 will be described later. Thereafter, in step S88, it is determined whether the door is open. If it is determined that the door is closed, the door opening flag is turned off in step S90, and the accumulated charge is displayed. And the packet which instruct | indicates the stop of the alarm unit 164 is transmitted by a PCL signal and radio | wireless communication, charging of the light emission parts 30 and 32 is stopped, and a flowchart is complete | finished. If it is determined that the door is open, the process returns to step S46.

  According to the first embodiment described with reference to FIG. 9, a sound generation alarm is issued after a certain time has elapsed after the door is opened, and if there is no response from the user, alarm light emission is performed. However, if there is no response from the user, the process of emitting the alarm light after the sounding alarm is repeated. Although explanation in the flowchart is omitted, when issuing an alarm instruction to the alarm unit 164, it is naturally considered to simultaneously issue an alarm instruction to all devices equipped with the alarm device according to the present invention, such as the fluorescent lamp 60. It is done. The same applies to the transmission of an alarm instruction to the alarm unit 164 described below.

  FIG. 10 is a flowchart showing in detail the calculation of the integrated fee in step S52 of FIG. This flowchart is started when the door opening flag is turned off. In step S100, the internal temperature when the door is closed is measured, and the temperature is held as the internal temperature when the door is closed. In step S102, the difference between the "door temperature when the door is closed" and the "door temperature when the door is open" is calculated. In step S104, the accumulated charge is calculated with reference to the table. This table may have seasonal factors. For example, even if the “door temperature when the door is open” is 12 ° C. in winter and the “door temperature when the door is closed” is 13 ° C., the temperature in the warehouse is lowered by 1 ° C. in winter compared to the summer. Less power consumption is required. Alternatively, the ambient temperature may be measured, and the power consumption required to return the temperature inside the cabinet to the temperature inside the cabinet when the door is not opened may be calculated. Here, the integrated fee is calculated using the temperature in the cabinet when the door is opened and the temperature in the cabinet when the door is closed, but the integrated fee may be calculated using other methods. For example, the accumulated charge may be calculated using excess power consumed to keep the temperature inside the cabinet constant even when the door is open. Moreover, the term “temperature in the cabinet” is used, and this applies to both the refrigerator compartment 14 and the freezer compartment 12. Moreover, the temperature table to be referred to may be provided separately for the refrigerator compartment 14 and the freezer compartment 12, and the parameters thereof may be different.

  FIG. 11 is a flowchart showing a detailed procedure of alarm light emission in step S84 of FIG. In step S110, a command to start charging the light emitting units 30 and 32 is issued, and in step S112, the amount of light in the surrounding environment is measured. The table is referred to according to the light amount measured in step S114, and the target light emission amount is set in step S116 in consideration of the light emission amount set by the user when the refrigerator 4 is installed. In step S118, it is determined whether or not electric charges corresponding to the target light emission amount are accumulated in the capacitors included in the light emitting units 30 and 32. If it is determined that charges are accumulated, light is emitted in step S120. In FIG. 11, the procedure is such that the charging of the capacitors of the light emitting units 30 and 32 is started upon receiving a light emission instruction from the microcomputer 16, but other procedures are also conceivable. For example, charging of the capacitor charge may be started as soon as the refrigerator 4 is turned on, and the light emitting units 30 and 32 may wait in a state where the capacitor charge is charged. If it does in that way, the light emission parts 30 and 32 can be light-emitted simultaneously with the light emission command from the microcomputer 16 being made. Although not described in the flowchart, when there are a plurality of light emitting units 30 and 32, it is conceivable that all the light emitting units 30 and 32 are simultaneously illuminated. According to this, it is possible to emit a light amount larger than the amount of light that can be emitted by one light emitting unit. In addition, when there are a plurality of light emitting units 30 and 32, it is possible to emit light with a light emission time interval shorter than the time interval of light emission of one light emitting unit by shifting the light emission timing.

  FIG. 12 is a flowchart showing details of the instruction to the alarm unit 164 shown in step S86 of FIG. In the figure, a unit warning instruction packet is transmitted by a PCL signal in step S130. In step S132, a unit warning instruction packet is transmitted wirelessly. Then, the flowchart ends.

  FIG. 13 is a flowchart for explaining details when the alarm stop button 54 of the refrigerator 4 is pressed. This flowchart is started when the alarm stop button 54 is pressed by the user. In step S140, the sound generation alarm is stopped, and in step S142, the alarm light emission is stopped. In step S146, the alarm stop packet is PLC transmitted to the other device, and in step S148, the alarm stop packet is wirelessly transmitted to the other device.

  FIG. 14 is a flowchart showing in detail the processing on the refrigerator 4 side when an alarm stop packet is transmitted from the fluorescent lamp 60 provided with an alarm device to the refrigerator 4 or another alarm unit 164. This flowchart starts when an alarm stop packet is transmitted from a fluorescent lamp 60 or other alarm unit 164 having an alarm device and received. The sound generation alarm is stopped in step S150, the alarm light emission is stopped in step S152, and the flowchart ends.

  FIG. 15 is a flowchart showing in detail the processing of the alarm unit 164 when the alarm unit 164 is installed in the outlet. This flowchart begins when the alarm unit 164 is plugged into an electrical outlet. In step S160, it is determined whether a unit alarm instruction packet is received. If it is determined that no packet has been received, the loop process is repeated. If it is determined in step S160 that a unit alarm instruction packet has been received, a sound generation alarm is generated in step S162. In step S164, an instruction to start charging the light emitting unit 224 is issued, and in step S166, it is determined whether or not a charge necessary for light emission is charged in the capacitor in the light emitting unit 224 of the alarm unit 164. If it is determined, the loop processing returning to step S166 is repeated. If it is determined in step S166 that the charge necessary for unit light emission is charged in the capacitor of the light emitting unit 224, the light emitting unit 224 emits light in step S168. In this flowchart, the alarm unit 164 is instructed to start charging the light emitting unit 224 after the sound generation alarm, but the order is not limited to this. For example, charging of the capacitor included in the light emitting unit 224 may be started at the same time as the alarm unit 164 is plugged into an outlet. Then, the procedure may be such that the capacitor always stands by while holding the charge necessary for light emission, and the light emitting unit 224 emits light simultaneously with receiving the unit alarm instruction packet.

  FIG. 16 is a flowchart showing details when the alarm stop button 225 is pressed on the alarm unit 164 side. This flowchart starts when an alarm stop button 225 provided in the alarm unit 164 is pressed. When the alarm stop button 225 is pressed in the alarm unit 164, the sound generation alarm of the alarm unit 164 is stopped in step S170, the alarm emission of the alarm unit 164 is stopped in step S172, and the refrigerator 4 and the like are stopped in step S174. An alarm stop packet is transmitted to the unit by PLC. Thereafter, in step S176, an alarm stop packet is wirelessly transmitted to the refrigerator 4 and other units, and the flowchart ends.

  FIG. 17 is a flowchart showing details when a unit alarm stop packet is received on the alarm unit 164 side. This flowchart is started when a unit alarm stop packet is received on the alarm unit 164 side. When the unit alarm stop packet is received, the sound generation alarm is stopped in step S180. In step S182, the alarm light emission is stopped and the flowchart ends.

  FIG. 18 relates to the second embodiment of the present invention, and is a flowchart for explaining in detail the procedure of alarm processing when the power of the refrigerator 4 is not supplied. The flowchart of FIG. 6 starts when it is detected that power is not supplied to the refrigerator 4. In step S192, the power supply flag is turned off, and the current time is held as the power non-supply start time. In step S194, the light quantity attenuation rate is calculated. Although details of the light amount attenuation rate in step S194 will be described later, this light amount attenuation rate is used to determine whether or not power is not supplied due to a power failure. In step S196, it is determined whether or not “the light amount attenuation rate is greater than 10 and the current light amount is 1 lux or less”. If it is determined that the light quantity attenuation rate is greater than 10 and the current light quantity is 1 lux or less, it is assumed that power is not supplied to the refrigerator 4 due to a power failure, and light emission is performed at step S198. Details of the light emission during a power failure will be described later. If it is determined in step S196 that the light quantity attenuation rate is greater than 10 and the current light quantity is not 1 lux or less, it is assumed that power is not supplied to the refrigerator 4 due to a cause other than a power failure, and the process proceeds to step S200. Proceed with. In step S200, counting for a certain time starts. In step S202, it is determined whether the counting time has reached a certain time. If it is determined that the certain time has not been reached, power supply is performed in step S204. It is determined whether or not the power supply has been restored. If it is determined that the power supply has been restored, the power supply flag is turned on in step S206, the power non-supply time is displayed, and the flowchart ends. If it is determined in step S204 that the power supply has not been restored, the process returns to step S202. If it is determined in step S202 that the count time has reached a fixed value, it is determined in step S208 whether the interpersonal sensor 56 is on. The determination as to whether or not the interpersonal sensor 56 is on is made for the purpose of shifting the alarm generation timing depending on whether or not there is a person around the refrigerator 4. If it is determined that the human sensor 56 is on, the counting is started for a certain time in step S210, and it is determined whether or not the counting time has reached a certain time in step S212. If it is determined that the power supply has not been reached, it is determined in step S214 whether the power supply has been restored. If it is determined in step S214 that the power supply has been restored, the power supply flag is turned on in step S216, the power non-supply time is displayed, and the flowchart ends. If it is determined in step S214 that the power supply has not been restored, the process returns to step S212. If it is determined in step S212 that the count time has reached a fixed value, a sound generation alarm process in step S218 is performed. The sound generation alarm process in step S218 is also a process when it is determined in step S208 that the interpersonal sensor 56 is off.

  After the sound generation warning process is performed in step S218, counting for a predetermined time starts in step S220. In step S222, a determination is made as to whether the count time has reached a constant value. If it is determined that the count time has reached a fixed value, a determination is made in step S224 as to whether the power supply has been restored. If it is determined that the power supply is not present, the power supply flag is turned on in step S226, the power non-supply time is displayed, and the flowchart is terminated. If it is determined in step S224 that the power supply has not been restored, the process returns to step S222. If it is determined in step S222 that the count time has reached a constant, a warning light emission process is performed in step S228. After the warning light emission process in step S228, an instruction is given to the warning unit 164 in step S230. After instructing the alarm unit 164 in step S230, it is determined in step S232 whether or not the power supply has been restored. If it is determined that the power supply has been restored, in step S234 the power supply is restored. Turn on the supply flag and display the power supply non-supply time. Then, a unit stop instruction packet is transmitted by a PCL signal and wireless transmission, charging of the light emitting units 30 and 32 is stopped, and the flowchart is ended. If it is determined in step S232 that the power supply has not been restored, the process returns to step S202.

  FIG. 19 is a flowchart for explaining in detail the procedure for holding the parameters used to calculate the light quantity attenuation rate in step S194 in FIG. This flowchart is started when the battery 22 for the microcomputer 16 of the refrigerator 4 is attached. In step S240, it is determined whether the second data of the current time is an integer multiple of 2. If the second data is not an integer multiple of 2, the process returns to step S240, and if the second data is an integer multiple of 2. In step S242, the amount of light around the refrigerator 4 is overwritten and retained in the “2 seconds ago light amount memory”.

  FIG. 20 is a flowchart for explaining in detail the procedure for calculating the light amount attenuation rate in step S194 in FIG. In step S250, it is determined whether the second data of the current time is an integer multiple of 2. If it is determined that the second data is not an integer multiple of 2, the process returns to step S250. If it is determined in step S250 that the second data of the current time is an integral multiple of 2, the current light amount is measured in step S252, and the light amount 2 seconds before from the “2 seconds previous light amount memory” in step S254. In step S256, a difference between the “current light amount” is obtained from the “two-second previous light amount memory”, and a value obtained by dividing the difference by 2 is defined as α. This α is a large value when the amount of light around the refrigerator 4 is rapidly attenuated. For example, when a power failure occurs, the amount of light around the refrigerator, which was 500 lux, drops to 0 lux. According to this example, 250 is calculated as α.

  FIG. 21 is a flowchart for explaining in detail a procedure for calculating a time during which power is not supplied. This flowchart starts when the power supply flag is turned off. After the power supply flag is turned off, it is determined in step S260 whether or not the power supply flag is on. If it is determined that the power supply flag is off, the process returns to step S260. If it is determined in step S260 that the power supply flag is on, the difference between the “current time” and the “power supply non-supply start time” is calculated in step S262, and the difference is held as the time when the power is off. The time when the power is off is displayed because it is considered that the user plays an important role in grasping the state of the food stored in the refrigerator 4.

  FIG. 22 is a flowchart for explaining in detail the power failure light emission in step S198 of FIG. According to this flowchart, light having a small light emission amount emits continuously at a short time interval as compared with normal alarm light emission. When the flowchart starts, first, in step S270, the target light emission amount is set to a minimum level. In step S272, a command to start charging the light emitting unit is issued. In step S274, it is determined whether or not a voltage corresponding to the target light emission amount is charged in the capacitor. Returning, if it is determined that the battery is charged, light is emitted in step S276. The light emission time interval can be shortened as the light emission amount is smaller than the normal light emission amount. In step S278, it is determined whether or not the ambient light amount is 1 lux or more. If it is determined that the ambient light amount is 1 lux or more, the ambient light amount is obtained, and it is not necessary to cause the light emitting units 30 and 32 to emit light. Determination is made and the light emission of the light emitting units 30 and 32 is terminated. If it is determined in step S278 that the ambient light amount is not 1 lux or more, it is determined in step S280 whether the alarm stop button 54 has been pressed. If it is determined that the button is not pressed, the process returns to step S274 to repeatedly emit the light emitting units 30 and 32. If it is determined that the alarm stop button 54 is pressed, the light emission of the light emitting units 30 and 32 is stopped and the flowchart is as follows. finish. If the light emitting units 30 and 32 are charged at the same time as the power of the refrigerator 4 is turned on and the electric charge is always stored in the capacitors provided in the light emitting units 30 and 32 even when the refrigerator 4 is normal, the light emission is possible. The step of the charge start command to the parts 30 and 32 becomes unnecessary. According to this, when a power failure occurs, it is possible to irradiate a darkened room immediately without waiting for the charging time.

  FIG. 23 relates to the third embodiment of the present invention, and is a flowchart for explaining in detail the procedure of alarm processing when the power of the refrigerator 4 is not supplied. Step S194 and step S196 in the flowchart of FIG. 18 are replaced with step S282 and step S284, and the other steps are common. In the second embodiment of the alarm processing when the power of the refrigerator 4 is not supplied, the first embodiment of the alarm processing when the power of the refrigerator 4 is not supplied is determined in the second embodiment of the alarm processing. It is easier than. The description of the portions having the same reference numerals in FIGS. 18 and 23 will be omitted, and the flowchart in FIG. 23 will be described with respect to steps S282 and S284 in FIG. In step S282, it is determined whether or not a power plug is inserted. If the power plug is inserted, the process proceeds to step S284, and it is determined whether or not the surrounding light quantity is 1 lux or more. If it is determined that it is 1 lux or more, it is determined that there is no power failure, and the flowchart ends. If it is determined in step S284 that the ambient light amount is 1 lux or less, blackout light emission is performed in step S198. If it is determined in step S282 that the power plug is not inserted, the process proceeds to step S200, and the process proceeds to a process for warning that the power plug is not inserted. In the third embodiment of the alarm processing when the power of the refrigerator 4 is not supplied, whether the power plug is inserted or not is used as a determination element for determining whether or not a power failure has occurred. A simple power failure determination without using 58 can be made.

  In the first embodiment to the third embodiment described above, the type of alarm is described only as to whether the door of the refrigerator 4 is open or whether the refrigerator 4 is not supplied with power. However, other types of alarms include failure of the refrigerator 4, abnormal temperature inside the refrigerator, or overloading of the refrigerator 4. Further, by providing the refrigerator 4 with an odor sensor, it is possible to make an alarm for whether there is any abnormality in the food in the refrigerator. Also, the user can investigate the determination line for whether or not to issue these warnings. Depending on the type of alarm, the type of alarm sound can be varied, the alarm volume can be adjusted, the emission pattern of the alarm emission can be varied, and the amount of alarm emission can be adjusted.

  FIG. 24 relates to the fourth embodiment of the present invention, and describes in detail the procedure of simultaneously performing alarm light emission and sounding alarm after a predetermined time has elapsed since the door of the refrigerator 4 was opened, and repeating these alarms. . This flowchart starts when the door of the refrigerator 4 is open. In step S300, counting for a fixed time is started, and a loop that proceeds to step S304 is repeated until the fixed time has elapsed in step S302. If it is determined in step S304 that the door is closed, the flowchart ends. If it is determined in step S304 that the door is open, the loop returning to step S302 is repeated. If it is determined in step S302 that the count time has reached a constant value, charging of the light emitting units 30 and 32 is started in step S306. In step S308, counting for a certain time is started, and in step S310, it is determined whether the counting time has reached a certain value. If it is determined in step S310 that the predetermined time has not been reached, it is determined in step S312 whether or not the door is open. If it is determined that the door is closed, the flowchart ends and the door is open. If it is determined, the process returns to step S310. If it is determined in step S310 that the count time has reached a certain time, alarm light is emitted in step S314, and a sound generation alarm is issued in step S316. Steps S314 and S316 are performed simultaneously. In step S318, it is determined whether an alarm instruction has been issued to the alarm unit 164. If the alarm instruction has not been issued, an alarm instruction is issued to the alarm unit 164 in step S320. The process proceeds to step S322 without giving an instruction. In step S322, it is determined whether the door of the refrigerator 4 is open. If it is determined that the door is closed, a unit alarm stop instruction is issued in step S324, and the light emitting unit is charged in step S326. Stop and the flowchart ends. If it is determined in step S322 that the door of the refrigerator 4 is open, it is necessary to repeatedly perform an alarm process. Therefore, the process returns to step S308, counts for a certain time, and then repeats a loop that proceeds to step S314.

  FIG. 25 relates to a fifth embodiment of the present invention, and describes in detail the procedure for issuing a sounding alarm after alarm light emission after a lapse of a certain time after the door of the refrigerator 4 is opened and repeating these alarms. FIG. 25 is a configuration in which step S330 and step S332 are newly added compared to FIG. 24, and therefore, the description of the corresponding configuration assigned the same number is omitted, and step S330 and step S332 are performed. Is mainly described. After the warning light is emitted, counting is started for a certain time in step S330. Then, in step S332, it is determined whether the count time has reached a constant, and the process of step S332 is repeated until the predetermined time has elapsed. If it is determined that the count time has reached a certain time, a sound generation alarm is issued in step S316. In the fifth embodiment realized by the flowchart of FIG. 25, a sounding alarm is performed after a certain time interval after alarm light emission. This time interval may be several seconds such as 0.1 seconds. This comma several seconds pays attention to the point that an ordinary person obtains incidental information by hearing or the like after recognizing things visually. In other words, it is intended that the natural timing of light and sound can be harmonized by repeating the operation of generating a sound to notify that the light has been emitted after the light alarm is given.

  FIG. 26 is a flowchart for explaining details of the processing on the alarm unit 164 side corresponding to the flowcharts of the fourth and fifth embodiments described in FIGS. 24 and 25. The flowchart starts when the alarm unit 164 is powered on. Then, unless the unit alarm instruction packet is received in step S340, the process of step S340 is repeated. When the unit alarm instruction packet is received, a charge start command is issued to the light emitting unit 224 in step S342, a fixed time count is started in step S344, and the loop process of step S346 is repeated until the fixed time has passed in step S346. . When a certain time has elapsed, a warning light is emitted in step S348, and a sound generation warning is issued in step S350. In step S352, it is determined whether a unit alarm stop packet has been received. If received, the flowchart ends. As long as it is not received, the loop which returns to step S342 after counting fixed time in step S356 is repeated.

FIG. 27 relates to the sixth embodiment of the present invention. Step S318 and step S320 in FIG. 23 are replaced with step S362 and step S364 in FIG. 27, and step S360 is added. According to this flowchart, step S36.
Since the charging start instruction packet is transmitted to the alarm unit 164 in advance at 0, the alarm light is emitted from the alarm unit 164 at the same time as the alarm light is emitted from the refrigerator. According to the present invention, the light emission of the refrigerator 4 and the light emission of the alarm unit 164 can be emitted simultaneously.

  FIG. 28 is a flowchart for explaining the details of the processing on the alarm unit 164 side corresponding to the sixth embodiment of the present invention described in FIG. The flowchart starts when the alarm unit 164 is powered on. In step S370, it is determined whether or not an alarm instruction packet has been received. Unless the alarm instruction packet has been received, the processing in step S370 is repeated. If an alarm instruction packet is received, charging is started in step S372. In step S374, it is determined whether a unit light emission instruction packet has been received. If it is determined, step S374 is repeated. If a unit light emission instruction packet is received in step S374, alarm light emission is performed in step S378, and a sound generation alarm is issued in step S380. In step S382, it is determined whether a unit alarm stop packet has been received. If it has been received, the flowchart ends. If not, the process proceeds to step S384 to start counting for a certain period of time. When the predetermined time elapses, the process returns to step S378 to repeat the alarm by the alarm light emission and the sound generation alarm.

  FIG. 29 relates to the seventh embodiment of the present invention, and determines the timing of light emission by measuring the charge amount of the capacitors provided in the light emitting sections 30 and 32. FIG. 29 is obtained by deleting step S308 in FIG. 24 and replacing step S310 in FIG. 24 with step S390. 29 with the same reference numerals as those in FIG. 24 are not described. When charging of the light emitting units 30 and 32 is started in step S306 of FIG. 29, it is determined in step S390 whether or not the amount of charge accumulated in the capacitors provided in the light emitting units 30 and 32 has reached a certain amount. To do. If it is determined that the predetermined amount has been reached, the process proceeds to step S314, and alarm light emission is performed. According to the seventh embodiment, since light emission is repeatedly performed based on the amount of charge accumulated in the capacitor, the control becomes simpler than when the light emission interval is determined using a counter or the like according to time.

  FIG. 30 relates to an eighth embodiment of the present invention. In FIG. 30, step S392 and step S394 are newly added compared to FIG. In step S392, counting of a certain time is started after the alarm emission is started, and the processing in step S394 is repeated until it is determined in step S394 that the counting time has reached a certain value. According to the eighth embodiment, the light warning is performed before the sound warning. Thereby, the same effect as the fifth embodiment can be obtained.

  FIG. 31 relates to the ninth embodiment of the present invention. FIG. 31 is obtained by adding step S402, step S404, step S406, and step S408 to FIG. In FIG. 31, after warning light is emitted in step S319, a sound generation warning is given in step S402. In step S404, counting is started for a certain time, and the processing in step S406 is repeated until the counting time reaches a certain value. If it is determined in step S6 that the certain time has elapsed, the light emitting unit 30, from the capacitor in step S408, The charge supply to 32 is stopped and light emission is stopped. According to the ninth embodiment of the present invention, when the light emitting units 30 and 32 are caused to emit light, all the charges accumulated in the capacitor are not released. As a result, the light emission interval can be shortened as compared with the case where light is emitted by discharging all charges accumulated in the capacitor. For example, what emitted light once every 3 seconds can be made to emit light once every 2 seconds with a slight decrease in light emission amount. Further, by reducing the electric charge to be released per light emission extremely and shortening the light emission interval, it is possible to play a role as an emergency light in a short time in the event of a power failure.

  FIG. 32 relates to a tenth embodiment of the present invention. In FIG. 32, step S330 and step S332 in FIG. 31 are replaced with step S420, step S422, step S424, and step S426. In FIG. 32, after a warning light is emitted in step S314, a sound generation warning is given in step S420. In step S422, counting for a certain time is started. In step S424, it is determined whether or not a certain time has elapsed. Until the certain time has elapsed, the process of counting time in step S424 is repeated. If it is determined that the predetermined time has elapsed, a sound generation alarm is issued in step S426, and the process proceeds to step S318. According to the tenth embodiment, the sound is generated twice for one light emission. Since the alarm due to light emission requires time to accumulate the electric charge in the capacitor, it is not possible to repeatedly emit light at short intervals while maintaining the light emission amount. be able to.

  FIG. 33 relates to the eleventh embodiment of the present invention. FIG. 33 is obtained by adding steps S432, S434, S436, and S438 to FIG. In FIG. 33, after the sound generation alarm is given in step S316, it is determined in step S432 whether or not the charge accumulated in the capacitor is below a certain level. If it is determined repeatedly that it is equal to or greater than a certain value, the emission of electric charge is stopped and light emission is stopped in step S434. When the light emission is stopped, the charge supplied from the charging means is accumulated in the capacitor from the charging means. If it is determined in step S436 that the charge amount has reached a certain level, warning light emission is performed in step S438. According to the eleventh embodiment, a sound alarm is performed once for a light alarm twice. This makes it easier to inform the user of the alarm in a noisy environment.

  FIG. 34 relates to the twelfth embodiment of the present invention. 34 is different from FIG. 24 in that step S300, step S302, step S304, step S306, step S308, step S310, step S312, step S314, step S324, and step S326 are common, and other steps are different. . If it is determined in step S310 in FIG. 34 that the count time has reached a certain level, a warning light is emitted in step S314. In step S439, counting for a certain time is started. In step S440, it is determined whether the counting time has reached a certain value. The counting process in step S440 is repeated until the certain time has elapsed. If it is determined that the predetermined time has elapsed, the sounding alarm is repeatedly activated in step S442. This repetitive sounding alarm issues a sound alarm at regular time intervals. Then, in step S446, it is determined whether or not the amount of charge accumulated in the capacitor has reached a certain level. If it is below the certain level, the charge measurement process in step S446 is repeated. If it is determined that the charge is equal to or greater than a certain level, it is determined in step S448 whether an alarm instruction has been issued to the alarm unit 164. An alarm instruction is issued, and if an alarm instruction has been given to the alarm unit 164, the process proceeds to step S452. In step S452, it is determined whether or not the door is open. If it is determined that the door is closed, the process proceeds to step S324. If it is determined that the door is open, it is determined in step S454 whether or not the light emission timing is within a certain period of time with the next sounding alarm timing. move on. When it is determined that the light emission timing is within a certain time with the next sounding alarm timing, sound generation is performed at the same timing as the next sounding in step S456. According to the invention of the twelfth embodiment, the alarm by the sound generation and the light emission is repeated for a certain period of time, but when the sound generation and the light emission are close in timing, It can be linked to sound and light alarms.

  FIG. 35 relates to the thirteenth embodiment of the present invention. This figure is a flowchart for explaining the details when the alarm packet is received from another device in the refrigerator 4, the alarm unit 164, and the fluorescent lamp 60. The flowchart in FIG. 35 starts when an alarm packet is received from another device by the PLC signal or the wireless reception unit 24. For example, when the alarm unit 164 receives an alarm packet from another device, charging of the light emitting unit 224 is started in step S460, and whether or not the alarm packet received in step S461 is an alarm packet from the safe. Make a decision. If it is determined that the alarm packet is from the safe, an alarm according to alarm pattern 1 is performed in step S462. Details of the alarm pattern 1 will be described later. If it is determined in step S461 that the alarm packet is not from the safe, it is determined whether or not the alarm packet received in step S464 is sent from the refrigerator 4. If it is determined that it is sent from the refrigerator 4, an alarm is issued according to the alarm pattern 2 in step S 466, and if not, an alarm according to the alarm pattern 3 is issued in step S 468. In step S470, it is determined whether an alarm stop packet has been received. If received, charging is stopped in step S471, and the flowchart ends. If it is determined in step S470 that an alarm stop packet has not been received, it is determined in step S472 whether or not the alarm stop button 225 has been pressed, and if it is determined that it has been pressed, charging is stopped in step S472. Then, the flowchart ends. If it is determined in step S471 that the alarm stop button 225 has not been pressed, the process returns to step S461 and the alarm process is repeated. According to the thirteenth embodiment, since the alarm pattern is varied depending on the type of device that has transmitted, it is possible to recognize from which device the alarm is generated.

  FIG. 36 is a flowchart showing details of alarm pattern 1 shown in step S462 of FIG. In FIG. 36, it is determined whether or not the charge amount has reached a constant in step S480, and the charge amount determination process in step S480 is repeated until it is determined that the charge amount has been reached. If it is determined in step S480 that the charge amount has reached a certain level, a warning light is emitted in step S482, a sound generation alarm is issued in step S484, and it is determined in step S486 whether the charge amount is below a certain level. . If it is determined that the charge amount is greater than or equal to a certain value, the charge measurement process in step S486 is repeated, and if it is determined that the charge amount has decreased to a certain value or less, light emission is stopped in step S488. Since the charging process is performed continuously, when the charge is accumulated until it is determined in step S490 that the charge amount is equal to or greater than a certain level, the alarm light emission is performed again in step S492. According to this alarm pattern 1, since the light alarm is performed more frequently than the sound alarm, and the light emitting unit emits light as frequently as possible, the user is informed that the alarm is highly urgent. It also becomes. If the user remembers the alarm pattern and the type of device, it can be recognized from which device the alarm is issued.

  FIG. 37 is a flowchart showing details of alarm pattern 2 shown in step S464 of FIG. In FIG. 37, the start of counting for a fixed time is started in step S500, and it is determined in step S502 whether or not the fixed time count has elapsed. If it is determined in step S502 that the count has elapsed, alarm light is emitted in step S504, and a sound generation alarm is issued in step S506. According to this flowchart, sound and light are repeated equally at regular intervals.

  FIG. 38 relates to the fourteenth embodiment of the present invention. FIG. 38 is different from the flowchart in FIG. 24 in that step S314 and step S316 are deleted, and step S510, step S512, and step S514 are inserted instead. The start condition of the flowchart is “abnormality detection”. The flowchart in FIG. 38 starts when an abnormality is detected, and after an intermediate process, it is determined in step S510 whether the abnormality is that the door of the refrigerator 4 remains open. When it is determined that the door of the refrigerator 4 is left open, an alarm is issued according to the alarm pattern 1 in step S512, and the process proceeds to step S318. If it is determined in step S510 that the abnormality does not remain open, an alarm using alarm pattern 2 is issued in step S514. According to the fourteenth embodiment, the light emission pattern can be made different depending on the abnormality occurring in itself.

  FIG. 39 relates to the fifteenth embodiment of the present invention. The flowchart of FIG. 39 starts when it is detected that power is not supplied to an alarm device (alarm unit 164 or the like). In step S550, the power supply flag is turned off and the current time is stored. Next, in step S552, it is determined whether or not the power plug is inserted. If the power plug is inserted, power failure is emitted in step S554, and the power plug is not inserted in step S552. If determined, light emission is performed when the plug is removed in step S556.

  FIG. 40 relates to the sixteenth embodiment of the present invention and is a flowchart showing in detail step S554 in FIG. In step S560 of FIG. 40, the light emitting units 30 and 32 are started to be charged. In step S562, a determination is made as to whether the amount of charge accumulated in the capacitor has reached a constant value. If it is determined that the charge amount has not reached a constant value, a determination is made in step S564 as to whether the power supply has been restored. If it is determined that the vehicle has returned, the flowchart ends. If it is determined that it has not returned, the process returns to step S562. If it is determined in step S562 that the amount of charge has reached a certain level, the light emitting units 30 and 32 are caused to emit light in step S566, and whether or not the amount of charge accumulated in the capacitor in step S568 is below a certain level. Determine whether. If it is determined that the charge amount is not below a certain level, the process returns to step S568. If it is determined that the charge is released by the light emission and the charge amount is below a certain level, the light emission is stopped in step S570. Then, in step S572, it is determined whether or not the number of times of light emission has been performed N times. If it has not reached N times, the process returns to step S562. If it is determined in step S574 that the number of times of light emission has reached N, it is determined in step S574 whether or not the power has been restored. If it is determined that the power is restored, the process proceeds to step S576, where an alarm stop instruction is transmitted to the unit, and charging of the light emitting units 30, 32 is stopped in step S578. If it is determined in step S574 that the power has not been restored, the process proceeds to step S580, and after a predetermined time has elapsed, the process returns to step S562. According to this embodiment, the light emitting units 30 and 32 perform steady light emission that repeats light emission that does not release all the electric charges of the capacitor once. Furthermore, if the count time in step S580 is lengthened, a steady light emission period and a light emission suspension period can be provided.

  FIG. 41 relates to the seventeenth embodiment of the present invention, which is obtained by adding step S582 to FIG. In the seventeenth embodiment of FIG. 41, by adding the counting process for a certain time in step S582, it is possible to emit light that does not release all charges and that has a light emission interval. According to this, in the case where no new charge is accumulated in the capacitor when a power failure occurs, it is possible to perform light emission so that the capacitor charge does not immediately disappear.

  As described above, the present invention includes an abnormality detection unit that detects a device abnormality and outputs a signal, and a booster that operates based on a signal output from the abnormality detection unit and boosts a supplied voltage. Provided is an alarm device comprising: a circuit; charge storage means for storing charge supplied from the booster circuit; and a light emitting unit that emits light using the charge stored in the charge storage means. . As a result, an abnormality is detected and flashing is performed, so that it is possible to issue an alarm that is not easily overlooked by the user. According to another feature of the invention, the alarm device starts measuring time based on a signal output from the abnormality detecting means, and outputs a signal when the measured time reaches a certain time, And a trigger circuit that outputs a signal for driving the light emitting unit based on a signal output from the time measuring means. According to this embodiment, since the light emitting unit is controlled by time control, it is possible to perform relatively simple control when detecting the charge accumulation amount and determining the light emission timing. According to another feature of the invention, the alarm device starts measuring time based on the time when the operation of the booster circuit is started, and outputs a signal when the measurement time reaches a certain time, And a trigger circuit that outputs a signal for driving the light emitting unit based on a signal output from the time measuring means. According to this embodiment, since the light emission timing is determined based on the operation of the booster circuit, the design can be easily performed.

  According to another aspect of the present invention, the alarm device includes a trigger circuit that outputs a signal for driving the light emitting unit when the amount of charge stored in the charge storage unit reaches a certain level. According to this embodiment, it is possible to perform a design in which timing adjustment is relatively easy. According to another feature of the invention, the abnormality detection means provided in the alarm device is output from a door open / close detection means for detecting that the door of the device is open and outputting a signal, and the door open / close detection means. And a time measuring means for starting time measurement based on the signal, wherein the charge storage means operates based on a signal output from the time measuring means. According to this embodiment, since the time measurement is started after the door is opened, it is possible to accurately measure the time during which the door remains open. According to another aspect of the present invention, the alarm device includes a trigger circuit that outputs a signal for driving the light emitting unit based on the second signal output from the time measuring unit. According to another aspect of the present invention, the alarm device includes a sound generation unit that generates sound at the same timing as the light emission unit emits light. According to this embodiment, since the light emission and the sound generation occur at the same timing, an alarm having a strong impact can be issued to the user.

  According to another aspect of the present invention, the alarm device includes a sounding unit that generates a sound after the light emitting unit emits light. According to this embodiment, after the light is emitted, a warning is given by sound generation, and after the normal human recognizes the change of the situation visually, the warning is issued in the same order as when the change of the situation is recognized at other intervals. Can be recognized. As a result, alarms can be generated in the natural order of the senses between them. According to another aspect of the present invention, the alarm device includes a sounding unit that generates a sound before the light emitting unit emits light. According to this embodiment, a sound alarm is given before light emission. After performing a soft warning by sound, if the user still does not recognize it, a more powerful warning is given. According to another characteristic of the present invention, the alarm device is characterized in that the light emission of the light emitting unit and the sound generation of the sounding unit are repeated at predetermined light emission intervals. According to this embodiment, since the alarm is performed a plurality of times, it is possible to issue an alarm that is not easily overlooked to the user. According to another feature of the present invention, the alarm device performs sound generation by the sound generation unit without light emission before the light emission interval elapses until the next light emission is performed after the light emission unit emits light. Features. According to this embodiment, the sound alarm can be performed more frequently than the light alarm, and the sound alarm can be frequently issued to the user even when the charging time interval of the light emitting unit is required. . According to another aspect of the present invention, the alarm device represents a plurality of light emission patterns by changing the light emission interval. According to this embodiment, a plurality of alarm patterns can be expressed. According to another feature of the present invention, the alarm device switches the light emission pattern based on the state of the device. According to this embodiment, it is possible to vary the pattern of alarms that are generated according to the abnormality occurring in the device. According to another feature of the present invention, the alarm device includes a transmission unit, and transmits the state from the transmission unit to an external device based on the state of the mounted device. According to this embodiment, it is possible to notify a device other than the device where the abnormality has occurred to the effect that the abnormality has occurred.

  According to another feature of the present invention, the alarm device does not release all of the charges accumulated in the charge accumulation means when the light emitting unit emits light. According to this embodiment, it is possible to emit light having a weak light emission amount or light emission intensity. According to another aspect of the invention, the alarm device does not interrupt the supply of charge from the booster circuit even when the charge accumulated in the charge accumulation means is released when the light emitting unit emits light. It is characterized by being performed. According to this embodiment, since the charge is always supplied, the interval until the next light emission can be shortened as compared with the case where the charge charging is interrupted every time the light is emitted. Another feature of the present invention is to provide a cooling device comprising a storage room for storing a cooling object, a cooling means for cooling the storage room, and an alarm device. According to another aspect of the present invention, the alarm device includes a trigger circuit that repeatedly triggers the light emitting unit after the charge accumulation by the charge accumulation unit is started. According to this embodiment, it is possible to issue a warning that is hardly overlooked to the user by repeatedly emitting light. According to another feature of the present invention, the trigger circuit provided in the alarm device triggers the light emitting unit every predetermined time. According to another feature of the present invention, the trigger circuit provided in the alarm device triggers the light emitting unit every time the charge storage means stores a charge up to a predetermined voltage. According to this embodiment, since light is emitted every time charge is accumulated, it is possible to perform control more easily than in the case where the light emission interval is controlled by time. According to another aspect of the present invention, the alarm device includes a sound generation unit that generates sound in synchronization with a trigger by the trigger circuit.

  According to this embodiment, since the alarm by sound is also performed in synchronization with the alarm by light, an alarm that is less likely to be overlooked by the user can be issued. According to another aspect of the present invention, the sound generation unit included in the alarm device is configured to generate sound after a predetermined delay from a trigger by the trigger circuit. According to this embodiment, sound generation is performed after light emission, so that after alarming visually, an alarm appealing to hearing can be performed. According to another feature of the present invention, the alarm device repeats sounding based on a signal output from the abnormality detecting means, and when the next sounding schedule is close to a triggering schedule by the trigger circuit for a predetermined time or more. And a control unit that synchronizes pronunciation with a trigger. According to this embodiment, in the case of issuing an alarm in which sound and light are repeated at a predetermined interval, the light alarm is disturbed by the charge charging speed and the light emission scheduled interval is disturbed, and the sound alarm and the alarm are shifted halfway. However, in the case where they are performed close to each other, it is possible to synchronize light and sound alarms. According to another aspect of the present invention, the control unit included in the alarm device causes the sound to be generated after a predetermined delay from the trigger when the sound generation is synchronized with the trigger.

  According to another feature of the present invention, the alarm device receives a failure detection signal from an external device, a booster circuit that operates based on the failure detection signal and boosts the supplied voltage, and the booster circuit Charge storage means for storing the charge supplied from the light source, and a light emitting section that emits light using the charge stored in the charge storage means. According to this embodiment, the alarm device can serve as an alarm device that generates an abnormality of an external device. According to another aspect of the present invention, the alarm device includes an illumination light generation unit that emits light constantly, and the light intensity of the light emission unit is greater than the light intensity of the illumination light generation unit. According to this embodiment, it is possible to avoid overlooking an alarm due to illumination light. According to another feature of the present invention, the alarm device includes a control unit that reduces the emission intensity from the light emitting unit when no illumination light is generated from the illumination light generating unit. According to this embodiment, when the illumination light is not lit, the light emission intensity of the light emitting unit is reduced as compared with when the illuminating light is lit. Is also possible. According to another feature of the present invention, the alarm device has a control unit that emits steady light from the light emitting unit when no illumination light is generated from the illumination light generating unit. According to this embodiment, for example, the light emitting unit can be used as an emergency light during a power failure. According to another aspect of the present invention, the alarm device includes a trigger circuit that repeatedly triggers the light emitting unit after the charge accumulation by the charge accumulation unit is started. According to this embodiment, design for timing control becomes unnecessary, and it is possible to repeat light emission as soon as electric charges are accumulated in the capacitor.

  According to another feature of the present invention, the receiving unit included in the alarm device receives an abnormality detection signal capable of identifying an external device from a plurality of external devices, and the trigger circuit is in accordance with the identified external device. The light emitting unit is triggered by different repeating patterns. According to this embodiment, the light emission pattern can be varied depending on the device in which an abnormality has occurred. According to another feature of the present invention, the alarm device detects an abnormality of the device and outputs an abnormality detection means, a flash light emission part, and the flash light emission part based on a signal output from the abnormality detection means. A trigger circuit for repeatedly triggering is provided. According to another aspect of the present invention, the alarm device includes a sound generation unit that generates sound in synchronization with a trigger by the trigger circuit. According to another aspect of the present invention, the sound generation unit included in the alarm device is configured to generate sound after a predetermined delay from a trigger by the trigger circuit. According to another feature of the present invention, the alarm device repeats sounding based on a signal output from the abnormality detecting means, and when the next sounding schedule is close to a triggering schedule by the trigger circuit for a predetermined time or more. And a control unit that synchronizes pronunciation with a trigger. According to another aspect of the present invention, the control unit included in the alarm device causes the sound to be generated after a predetermined delay from the trigger when the sound generation is synchronized with the trigger.

  According to another aspect of the invention, the alarm device includes a receiving unit that receives an abnormality detection signal from an external device, a flash light emitting unit, and a trigger circuit that repeatedly triggers the flash light emitting unit based on the abnormality detection signal. It is provided with the alarm device characterized by this. According to this embodiment, a device that has received an abnormality detection of an external device can repeatedly emit light, and the role can be substituted even when the external device does not include alarm means. According to another aspect of the present invention, the alarm device includes an illumination light generation unit that emits light constantly, and the light intensity of the flash light emission unit is greater than the light intensity of the illumination light generation unit. According to another aspect of the present invention, the receiving unit included in the alarm device receives an abnormality detection signal capable of specifying an external device from a plurality of external devices, and the trigger circuit is in accordance with the specified external device. The light emitting unit is triggered by different repeating patterns. According to this embodiment, the alarm pattern can be varied according to the device in which an abnormality has occurred. According to another feature of the present invention, the alarm device repeatedly detects the abnormality of the device and outputs a signal, an abnormality detection unit that outputs a signal, a sound generation unit, and the sound generation unit based on a signal output from the abnormality detection unit It is characterized by having a sound generation control unit for generating sound and a transmission unit for repeatedly transmitting an abnormality warning signal to the outside in synchronization with the sound generation control by the sound generation control unit. According to this embodiment, when an abnormality occurs in itself, it is possible to notify other devices that the abnormality has occurred. According to another aspect of the present invention, the sound generation control unit included in the alarm device causes the sound generation unit to sound after a predetermined delay from the transmission of the abnormality warning signal by the transmission unit. In this embodiment, attention is paid to the fact that an ordinary person obtains incidental information by hearing or the like after visually recognizing things. In other words, it is intended that the natural timing of light and sound can be harmonized by repeating the operation of generating a sound to notify that the light has been emitted after the light alarm is given.

  Further, the present invention provides a power supply unit to which an AC voltage supplied from a commercial power supply is input, a booster circuit that boosts a voltage supplied from the power supply unit to generate a DC voltage, and is supplied from the booster circuit A flash light emission comprising: charge storage means for storing charge; a light emitting section that emits light using the charge supplied from the charge storage means; and a control section that controls a light emission pattern of the light emitting section. Providing the device. Since the flash emission is performed using the electric charge supplied from the commercial power source, it is possible to increase the frequency of the emission compared to the case where the flash emission is performed using a dry battery or the like. According to another feature of the present invention, the flash light emitting device of the present invention is characterized in that not all the charges accumulated in the charge accumulating means are emitted by one light emission. Since the charges accumulated in the charge accumulating means are not released at once, a plurality of light emission patterns can be realized. According to the present invention, in the case where a new charge is not supplied to the charge accumulating means in the event of a power failure or the like, the instantaneous light emission intensity is weakened by not emitting all the charges with one light emission, and instead the light emission is performed. You can increase the number of times.

  According to another feature of the present invention, the flash light emitting device of the present invention is characterized in that the light emitting unit of the control unit emits light repeatedly. According to the present invention, the smaller the amount of electric charge emitted by one emission, the lower the emission intensity, but the number of emission can be increased accordingly. When the surroundings become completely dark at the time of a power failure, even if the light with low emission intensity illuminates the room a plurality of times, the light is sufficiently useful for finding what is where.

  According to another aspect of the present invention, the light emission interval of the repeated light emission of the flash light emitting device of the present invention is variable. According to the present invention, a light emission interval from a certain light emission start timing to the next light emission start timing can be set long, and a time during which the charge accumulated in the charge accumulation means is not released can be provided at that interval. Thus, even when no charge is accumulated in the charge accumulating means when a power failure occurs, light emission for a long time is repeated even after the power failure occurs. Since the light emission interval is short, the field of view is worse than when the light emission interval is long, but it is still useful light for finding what is where.

  According to another feature of the present invention, the flash light emitting device of the present invention includes a power failure detection means, and the control portion causes the light emitting portion to emit light repeatedly when a power failure is detected. According to the present invention, when a power failure is detected, the light emitting unit automatically repeats light emission, and light can be obtained even when a power failure occurs. According to another feature of the present invention, the flash light emitting device of the present invention is characterized in that the light emission interval of repeated light emission in the event of a power failure is set so as to be substantially constant light emission. According to the present invention, light similar to the light emitted from a fluorescent lamp can be obtained for a certain period of time even after a power failure. According to another feature of the present invention, in the flash light emitting device of the present invention, the light emission in the steady light is continuous light emission, and the maximum light emission intensity of each light emission releases all charges at once. It is characterized by being smaller than the intensity of light generated in some cases. According to the present invention, it is possible to emit light having a lower light intensity for a certain period of time than the flash emission emitted by the imaging device.

  According to another aspect of the present invention, the flash light emitting device of the present invention includes a fluorescent light emitting unit. Even if a power failure occurs when a fluorescent lamp equipped with a fluorescent light emitting unit and a flash light emitting device is installed in the room, the flash light emitting unit is installed at a position where light spreads throughout the room, so the light emission time is short Even flashing light can emit light that illuminates the entire room. According to another aspect of the present invention, the flash light emitting device of the present invention generates a DC voltage by boosting a voltage supplied from an AC voltage supplied from a commercial power supply and the voltage supplied from the power supply. Boosting circuit, a charge accumulating unit for accumulating the charge supplied from the boosting circuit, a light emitting unit that emits light using the charge supplied from the charge accumulating unit, and an electric charge accumulated in the charge accumulating unit It is characterized by comprising a first light emission pattern that causes continuous light emission intermittently at a constant light emission interval without using all in one light emission, and a control unit that repeats a pause period during which the light emission part does not emit light. According to the present invention, the light emitting unit repeats steady light emission and pause time. Compared to a case where the light emitting unit always emits steady light, such as during a power failure, the time until all the charges accumulated in the charge are released can be extended.

  According to another aspect of the present invention, the flash light emitting device of the present invention is characterized in that the flash light emitting device includes a DC voltage generating unit that converts an AC voltage supplied from a commercial power source into a DC voltage. Unlike ordinary home appliances, this is considered to be necessary when a flashlight device is provided in a fluorescent lamp or the like that does not have a DC voltage generator. According to another aspect of the present invention, the control unit included in the flash light emitting device of the present invention selects either the first light emission pattern for flashing the light emitting unit or the second light emission pattern for continuously emitting the light emitting unit. It is possible. As a result, the flashlight emitting device can emit a plurality of patterns. According to another aspect of the present invention, the second light emission pattern emitted by the flash light emitting device of the present invention is substantially steady light emission, and the average light emission intensity is the maximum light emission in the first light emission pattern. It is characterized by being smaller than strength.

  According to another feature of the present invention, the second light emission pattern emitted by the flash light emitting device of the present invention is a continuous light emission, and the maximum light emission intensity of each light emission is the maximum light emission in the first light emission pattern. It is characterized by being smaller than strength. As a result, the flash light emitting device of the present invention can selectively perform flash light emission with a high light emission intensity for discharging charges at once and steady light emission with a low light emission intensity. According to another feature of the present invention, in the first light emission pattern of the flash light emitting device of the present invention, the charge of the charge storage means is discharged at a time, and a plurality of charges of the charge storage means are discharged in the second light emission pattern. The discharge is divided into times. According to another feature of the present invention, the control unit included in the flash light emitting device included in the present invention causes the light emitting unit to emit light in the first light emission pattern in response to detection of an abnormality, and the light emission in response to detection of a power failure The portion is caused to emit light with the second light emission pattern. Thereby, the light emission pattern of the light emitted from the light emitting unit can be varied depending on the type of abnormality detected. When warning the user of an abnormality with a high degree of urgency, it is possible to emit light with increased emission frequency or emit light with high emission intensity.

  According to another feature of the present invention, a flash light emitting device provided in the present invention includes a first light emitting unit, a power supply unit, a voltage supplied from the power supply unit, and a booster circuit that generates a DC voltage, Charge accumulation means for accumulating charges supplied from the booster circuit, a second issuance section that emits light using the charges supplied from the charge accumulation means, and the second light emission section from the first light emission section And a control unit that causes the second light emitting unit to emit light with one of the second light emitting patterns that emit light with a lower intensity than the first light emitting unit. As a result, the flash light emitting device of the present invention can selectively perform flash light emission with a high light emission intensity for discharging charges at once and steady light emission with a low light emission intensity. According to another aspect of the present invention, the flash light emitting device provided in the present invention is characterized in that the second light emission pattern is substantially steady-state light emission. Thereby, even in the event of a power failure, the user can obtain the steady light from the light emitting unit for a time long enough to recognize what is where. According to another feature of the present invention, the control unit included in the flash light emitting device included in the present invention causes the light emitting unit to emit light in a first light emission pattern in response to detection of an abnormality, and the light emission in response to detection of a power failure. The portion is caused to emit light with the second light emission pattern. Thereby, the light emission pattern at the time of detecting a power failure and different abnormality can be made different.

  This is useful in providing an alarm device that issues an alarm that the user does not overlook.

Claims (20)

A booster circuit that operates based on the abnormality detection signal and starts boosting the supplied voltage;
Charge storage means for storing charge supplied from the booster circuit;
A light emitting unit that emits light using the charge accumulated in the charge accumulation unit;
An alarm device comprising:   The alarm device according to claim 1, further comprising an abnormality detection unit that detects an abnormality of a device in which the alarm device is installed and outputs the abnormality detection signal. It has door opening / closing detection means for detecting that the door of the device is open and outputting a signal,
3. The abnormality detection unit according to claim 2, wherein the abnormality detection unit starts counting the time based on a signal output from the door opening / closing detection unit and outputs the abnormality detection signal when the count time reaches a predetermined value. Alarm device.   The alarm device according to claim 1, further comprising receiving means for receiving the abnormality detection signal from an external device.   The alarm device according to claim 4, further comprising an illumination light generation unit that emits light constantly, wherein the light intensity of the light emission unit is greater than the light intensity of the illumination light generation unit.   An AC voltage supplied from a commercial power supply is input, and a power supply unit that converts the AC voltage into a DC voltage and outputs the same is provided, and the booster circuit boosts the voltage supplied from the power supply unit. Item 1. An alarm device according to item 1.   The alarm device according to claim 1, further comprising a control unit that starts a time count based on the abnormality detection signal and outputs a trigger signal for driving the light emitting unit when the count time reaches a predetermined value.   2. The alarm device according to claim 1, further comprising a control unit that outputs a trigger signal for driving the light emitting unit when the amount of charge stored in the charge storage unit reaches a certain level. A booster circuit that boosts the supplied voltage;
Charge storage means for storing charge supplied from the booster circuit;
A light emitting unit that emits light using the charge accumulated in the charge accumulation unit;
The pronunciation part;
A control unit that synchronizes a sound generation signal to be generated by the sound generation unit based on an abnormality detection signal and a trigger signal for driving the light emitting unit;
An alarm device comprising:   The control unit operates based on the abnormality detection signal to start boosting of the booster circuit, and synchronizes with the trigger signal in a state where the charge of the charge storage unit is sufficient for light emission of the light emitting unit. The alarm device according to claim 9, wherein the sound generation signal is generated.   11. The alarm according to claim 10, wherein the control unit starts time counting based on the abnormality detection signal and outputs the trigger signal and the sound generation signal in synchronization when the count time reaches a predetermined value. apparatus.   11. The alarm device according to claim 10, wherein the control unit outputs the trigger signal and the sounding signal in synchronization when detecting that the amount of charge accumulated in the charge accumulating unit reaches a certain level.   10. The alarm device according to claim 9, wherein the control unit synchronizes the sound generation signal with the trigger when the next sound generation signal generation schedule and the trigger signal generation schedule are close to each other for a predetermined time or more. An abnormality detection means for detecting an abnormality of the device and outputting an abnormality detection signal;
The pronunciation part;
A control unit that outputs a sound generation signal that causes the sound generation unit to generate a sound based on the abnormality detection signal;
A transmitter for transmitting an abnormality warning signal to the outside based on the abnormality detection signal;
An alarm device comprising: Receiving means for receiving an abnormality detection signal from an external device;
A booster circuit that boosts the supplied voltage;
Charge storage means for storing charge supplied from the booster circuit;
A light emitting unit that emits light using the charge accumulated in the charge accumulation unit;
A control unit for generating a trigger signal for driving the light emitting unit based on the abnormality detection signal;
An alarm device comprising:   The receiving unit can receive the abnormality detection signal from a plurality of identifiable external devices, and the control unit emits different light that can be identified by the light emitting unit according to the specified external device. 16. The alarm device according to claim 15, wherein a trigger signal is generated.   16. The alarm device according to claim 15, further comprising an illumination light generation unit that emits light constantly, wherein the light intensity of the light emission unit is greater than the light intensity of the illumination light generation unit.   The alarm device according to claim 17, further comprising a control unit that reduces a light emission intensity from the light emitting unit when no illumination light is generated from the illumination light generating unit.   A power supply unit to which an AC voltage supplied from a commercial power supply is input for the illumination light generation unit; and a conversion unit that converts the input AC voltage to a DC voltage and supplies the DC voltage to the booster circuit. 18. The alarm device according to claim 17, wherein when the AC voltage is not supplied from the AC power source to the illumination light uttering unit, the unit causes the light emitting unit to emit light by the charge of the charge storage unit.   When no AC voltage is supplied from the AC power source to the illuminating light uttering unit, the control unit consumes a part of the charge of the light-emitting unit and charges the light-emitting unit repeatedly with low light intensity. 20. The alarm device according to claim 19, wherein:

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