JP5156563B2 - Alarm - Google Patents

Description

  The present invention relates to an alarm device that notifies an alarm when an environmental value indicating an environmental change exceeds an allowable range, and relates to a battery-operated alarm device that operates by power supply by a battery.

  2. Description of the Related Art Conventionally, an alarm device that issues an alarm when an abnormality in an indoor environment is detected has been widely used in buildings, underground malls, ordinary houses, and the like. As such an alarm device, an alarm device that performs fire detection or gas detection by detecting smoke, heat, gas, or the like, which is an environmental value representing an environmental change, is generally popular. Also, an alarm device for detecting a human body that detects a suspicious person by providing a human sensor such as an infrared sensor that detects far infrared rays emitted by a human body is also provided.

  Among these various alarm devices, those that are intended for installation in general homes are battery-operated alarms that use a battery rather than a commercial power supply to simplify wiring. A vessel has been proposed. In recent years, batteries having a large battery capacity, such as nickel-based primary batteries in primary batteries and lithium ion batteries in secondary batteries, have been widely used. The battery replacement time of the alarm device becomes longer by installing it in the. However, even if the battery replacement time becomes longer, the power supply is stopped due to the battery running out, so that the battery-operated alarm device needs a function of notifying the battery running out.

As a battery-operated alarm device having a function of notifying that the battery has run out, the battery voltage is measured every predetermined time, and the battery voltage is compared with a threshold value to determine whether or not it is necessary to notify that the battery has run out. Has been proposed (see Patent Document 1). When the measured battery voltage falls below the threshold value a predetermined number of times, the alarm device of Patent Document 1 confirms whether or not the battery voltage has exceeded the threshold value based on a rise in the temperature around the alarm device, and runs out of the battery. Decide whether to notify. Thereby, it is possible to prevent battery exhaustion from being reported at night when the ambient temperature is low. In addition, if the battery voltage does not exceed the threshold for a predetermined time after the measured battery voltage continuously falls below the threshold value, the battery voltage is considered to be out of charge regardless of the time zone. Is notified.
JP 2008-134973 A

  As described above, there has been proposed a conventional battery-operated alarm having a function of measuring a battery voltage every predetermined time and notifying the outside of the battery. However, the conventional battery-operated alarm device that can notify that the battery has run out does not notify the remaining battery level of the mounted battery. Therefore, even if the user is informed that the battery has run out by the alarm device, the user cannot determine whether the battery replacement time is sufficient or whether the battery needs to be replaced urgently. Moreover, since the alarm device automatically notifies the battery exhaustion, when the user is absent, the alarm device may notify the battery exhaustion. When the user wants to check, the alarm device I cannot check the battery level.

  In view of such a problem, the present invention is configured to be able to measure the battery voltage and notify the remaining battery level according to the user's request, so that the user can check the remaining battery level at a desired timing and The purpose is to propose an alarm device that can recognize the alarm.

In order to achieve the above object, an alarm device of the present invention includes a voltage detection unit that detects a battery voltage, a signal processing unit that determines whether the battery has run out based on the battery voltage detected by the voltage detection unit, A battery-operated alarm device comprising: a notification unit for notifying the outside of the battery when the signal processing unit confirms that the battery has run out; an operation switch for receiving a command for detecting the remaining battery power; and an alarm device from the battery A supply current amount switching unit for increasing the amount of current supplied to the main body, wherein the signal processing unit stores a plurality of threshold values for determining whether the battery is exhausted, and the plurality of threshold values at a predetermined timing The battery voltage is detected by comparing with the battery voltage detected by the voltage detection unit, and the supply current switching unit is driven from a state in which the supply current amount switching unit is not driven. If the remaining battery level is detected at the same time based on the amount of change in battery voltage when the current level is changed to an increased state, it is confirmed that the remaining battery level is low. Is changed to a shorter time interval, and when the operation switch accepts a command for detecting the remaining battery level, the notification unit notifies the remaining battery level, and the notification by the notification unit depends on the remaining battery level. It is characterized by changing gradually.

In the alarm device, the operation switch may further include a function as a test operation switch that receives a test operation command for confirming the operation of the main body. Then, it may be determined whether the command is a test operation or a battery remaining amount detection operation according to an operation time or an operation pattern for the operation switch.

  According to the present invention, when a command to the operation switch is received, the battery voltage is detected and the remaining battery level is notified, which is different from the conventional case where the battery is informed regardless of the presence or absence of the user. The remaining battery level can be confirmed at a timing desired by the user, and the user can be reliably notified of the remaining battery level. Therefore, since the user can confirm the remaining battery level of the alarm device and recognize the life until the battery runs out, the user can predict the timing of the battery running out of the alarm device. Therefore, even when the user has not confirmed the alarm of the battery exhausted by the alarm device, the user operates the operation switch at the expected battery exhaustion timing to determine the remaining battery level notified from the alarm device. You can confirm that the battery is dead.

<First Embodiment>
An alarm device according to a first embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing the internal configuration of the alarm device of the present embodiment, and FIG. 2 is a schematic external view showing the configuration of the alarm device of the present embodiment.

  As shown in FIG. 1, the alarm device 1 detects a battery 11 serving as a power source for supplying power, a detection unit 12 that measures environmental values such as detection of smoke, gas, or heat, and a battery voltage of the battery 11. From the voltage detection unit 13, the signal processing unit 14 that receives the detection signal from the detection unit 12 and the measurement signal from the voltage detection unit 13 and controls the operation of the detection unit 12 and the voltage detection unit 13, and the signal processing unit 14 Is provided with a notification unit 15 that performs a notification operation such as voice output, image display, and light emission operation, an operation switch 16 that receives an operation from the outside, and a timer 17 that measures time. The battery 11 may be a primary battery that cannot supply power after complete discharge, or may be a secondary battery that can supply power many times by charging. The battery 11 supplies electric power to each of the detection unit 12, the voltage detection unit 13, the signal processing unit 14, the notification unit 15, and the timer 17.

  As shown in FIG. 2, the alarm device 1 having such a configuration is formed with a detection unit 12 on the front end side of the casing constituting the alarm device 1, and on the outer peripheral side centering on the detection unit 12, A sounding body 51, a display unit 52, a light emitting unit 53, and an operation switch 16 using a drawstring constituting the notification unit 15 are arranged. Moreover, in the housing | casing which comprises the alarm device 1, the opposite side to the side in which the detection part 12 was installed becomes an installation surface, and is installed in a floor or a wall. The configuration of the alarm device 1 shown in the external view of FIG. 1 is an example. For example, the sounding body 51 may be disposed further on the front end side of the detection unit 12.

  When the alarm device 1 is a fire detection alarm device, the detection unit 12 includes an optical smoke detection sensor including a light emitting element, a light receiving element, and an optical component, or a heat detection sensor using a thermistor. It is said. Further, when the alarm device 1 is an alarm device for gas detection, the gas amount is measured by the detection unit 12. Furthermore, the detection unit 12 is configured as a human body detection sensor configured by an infrared sensor that receives infrared rays emitted from the human body existing around the main body of the alarm device 1, and the alarm device 1 is configured as an alarm device for crime prevention by human body detection. May be. As shown in FIG. 2, the operation switch 16 may be constituted by a pull string for accepting an operation to the alarm device 1, or may be constituted by a button protruding from the casing constituting the alarm device 1. It is good also as a thing.

  And the sounding body 51 which becomes a part of the alerting | reporting part 15 may be comprised with the piezoelectric buzzer which alert | reports by a buzzer sound, and may be comprised with the speaker which reproduces | regenerates and outputs alarm content and abnormal content as a sound. . Similarly, the display unit 52, which is a part of the notification unit, is configured by a liquid crystal display or an organic EL (Electro Luminescence) display that can display the alarm content, the remaining battery level, and the like, and the light emitting unit 53 is a blinking or lighting LED ( Light Emitted Diode). In addition to the sound generator 51, the display unit 52, and the light emitting unit 53, a vibration motor that vibrates the main body of the alarm device 1 is provided as a part of the notification unit 15, and a notification operation is performed by vibration of the main body of the alarm device 1. It is good also as what performs.

1. Alarm Notification In the alarm device 1 configured as described above, when the environmental value measured by the detection unit 12 is given to the signal processing unit 14, the measured environmental value reaches the warning range in the signal processing unit 14. It is confirmed whether or not. For example, when the alarm device 1 is an alarm device for fire detection and the smoke amount or the heat amount is measured as an environmental value by the detection unit 12, an electrical signal (detection signal) based on the environmental value measured by the detection unit 12 is generated. The signal processing unit 14 is given. Then, when the signal processing unit 14 recognizes the smoke amount or the heat amount from the detection signal received from the detection unit 12 and confirms that the measured smoke amount or the heat amount is larger or higher than a threshold value that is an alarm area, It is determined that the alarm notification operation is started.

  When the signal processing unit 14 determines that the alarm notification operation is started, the determination result is given to the notification unit 15, thereby giving a command to start alarm notification. In the notification unit 15 to which an instruction to start the alarm notification operation is given, the sounding body 51 issues an alarm and the display unit 52 displays the alarm content. At this time, the display unit 52 or the light emitting unit 53 may perform a blinking operation or a lighting operation according to the alarm content, or perform a blinking operation or a lighting operation according to the alarm content together with the display of the alarm content. Also good. Further, when a vibration motor or the like is provided as a part of the notification unit 15, the vibration motor or the like operates by a vibration pattern corresponding to the alarm content, and vibrates the main body of the alarm device 1 using a vibration pattern corresponding to the alarm content.

2. Notification of Battery Outage The battery outage notification operation in the alarm device 1 that performs alarm notification in this manner will be described below with reference to FIG. FIG. 3 schematically shows changes in battery voltage with respect to discharge time in battery 11. As shown in FIG. 3, after the battery voltage of the battery 11 gradually decreases from the maximum battery voltage Vmax at the start of discharge as the discharge time elapses, the battery voltage rapidly decreases as the battery life approaches. To do. Therefore, the alarm device 1 notifies the outside that the battery has run out before the battery voltage rapidly decreases by the notification unit 15. Therefore, the signal processing unit 14 stores a threshold voltage Vth1 that is higher than the battery voltage at which the rate of change of the battery voltage changes rapidly from a gradual change, and the battery voltage of the battery 11 is lower than the threshold voltage Vth1. Is confirmed, the notification unit 15 is instructed to notify that the battery has run out.

  The signal processing unit 14 further stores a threshold voltage Vth2 that is a voltage between the threshold voltage Vth1 and the maximum battery voltage Vmax. Thereby, when the signal processing unit 14 first confirms that the battery voltage of the battery 11 has decreased below the threshold voltage Vth2, the signal processing unit 14 notifies the notification unit 15 that the battery is preliminarily exhausted (preliminary notification). Further, when it is confirmed that the battery voltage of the battery 11 is lower than the threshold voltage Vth1, the notification unit 15 notifies that the battery has run out (this notification). When operating in this manner, the value of the threshold voltage Vth2 is preferably closer to the threshold voltage Vth1 than the maximum battery voltage Vmax.

  That is, the signal processing unit 14 determines whether or not the battery voltage measurement timing of the battery 11 has come based on the time measured by the timer 17, and confirms that the battery voltage measurement timing has come. The detector 13 is driven to measure the battery voltage of the battery 11. When the signal processing unit 14 receives the measurement signal indicating the battery voltage of the battery 11 measured by the voltage detection unit 13, the signal processing unit 14 compares the battery voltage of the battery 11 confirmed from the measurement signal with the threshold voltage Vth2. . At this time, when the battery voltage of the battery 11 is higher than the threshold voltage Vth2, the power supply of the voltage detection unit 13 is stopped, the voltage detection unit 13 is turned off, and the standby state is set until the next battery voltage measurement timing. .

  On the other hand, when the signal processing unit 14 confirms that the battery voltage of the battery 11 confirmed from the measurement signal received from the voltage detection unit 13 is lower than the threshold voltage Vth2, the battery voltage of the battery 11 and the threshold voltage are further increased. Compare with Vth1. At this time, when the battery voltage of the battery 11 is higher than the threshold voltage Vth1, the signal processing unit 14 provides the notification unit 15 with a control signal for performing preliminary notification. Thereby, the alerting | reporting part 15 drives the sounding body 51, the display part 52, the light emission part 53, etc., and performs preliminary alerting | reporting of a battery exhaustion. In this case, when the preliminary notification that the battery is exhausted is performed, the battery remaining amount detection operation described later is performed by the signal processing unit 14, and the remaining battery level of the battery 11 is notified by the notification unit 15.

  When the signal processing unit 14 confirms that the battery voltage of the battery 11 confirmed from the measurement signal received from the voltage detection unit 13 is lower than the threshold voltage Vth1, the signal processing unit 14 performs this notification. A control signal is provided to the notification unit 15. Thereby, the notification unit 15 drives the sounding body 51, the display unit 52, the light emitting unit 53, and the like, and performs the main notification that the battery has run out in order to prompt the user to replace the battery 11.

  In the above description, the signal processing unit 14 always performs comparison with the threshold voltage Vth2 after the preliminary notification by the notification unit 15, but may store whether or not the preliminary notification is performed using a flag or the like. That is, the signal processing unit 14 stores the fact that the preliminary notification has been performed after instructing the notification unit 15 to perform the preliminary notification that the battery has run out. At the next battery voltage measurement timing, the signal processing unit 14 stores the battery voltage and threshold value. Only the necessity of this notification is determined by comparing with the voltage Vth1. As a result, after the preliminary notification of the battery exhaustion for the first time, the signal processing unit 14 performs the preliminary notification of the battery exhaustion and the main notification only by comparing with the threshold voltage Vth1 every time the measurement timing of the battery 11 is reached. Determine which to do.

3. Notification of Battery Remaining Furthermore, a battery exhaustion notification operation in the alarm device 1 that detects the battery voltage will be described below with reference to FIG. FIG. 4 is a diagram illustrating a relationship between the battery remaining amount display on the display unit 52 and the battery voltage of the battery 11. Hereinafter, in order to simplify the description, it is assumed that the remaining battery level of the battery 11 is notified by displaying and hiding the nine scales 52-0 to 52-8 on the display unit 52. It should be noted that the number of scales for notifying the remaining battery level of the battery 11 by being displayed on the display unit 52 may be a substantial number for notifying so that a plurality of remaining battery levels can be reported. It is not limited.

  When the operation unit of the operation switch 16 is operated by the user, the switch unit of the operation switch 16 electrically connected to the signal processing unit 14 is turned on, and an electric signal is given. Therefore, the signal processing unit 14 receives an electric signal from the operation switch 16 and receives a command from the operation switch 16. The operation switch 16 accepts commands for other functional operations such as a test operation command for operation confirmation and an operation return command after alarm notification, in addition to the battery remaining amount detection operation command. As a result, it is not necessary to provide a special command only for the battery remaining amount detection operation. At this time, the period during which the switch part of the operation switch 16 is turned on when a command for detecting the remaining battery capacity is issued, and the period during which the switch part of the operation switch 16 is turned on when other instructions are given. Thus, the signal processing unit 14 may be able to specify the command received by the operation switch 16.

  When the operation switch 16 receives a command for detecting the remaining battery level and an electric signal corresponding to the received command is input to the signal processing unit 14, the signal processing unit 14 performs the remaining battery level detecting operation. Start. Thereby, the signal processing unit 14 drives the voltage detection unit 13 to measure the battery voltage of the battery 11. When the voltage detection unit 13 measures the measured battery voltage of the battery 11, the voltage detection unit 13 sends the measured battery voltage to the signal processing unit 14 as a measurement signal. The signal processing unit 14 that has received the measurement signal from the voltage detection unit 13 calculates the remaining battery level based on the battery voltage of the battery 11 to be confirmed from the measurement signal, and displays the scale 52 on the display unit 52 of the notification unit 15. Determine the number of scales from -0 to 52-8.

  At this time, in the display unit 52 to which the control signal is given by the signal processing unit 14, the battery voltage V of the battery 11 is Vth1 + N × (Vmax−Vth1) / 8 <V ≦ Vth1 + (N + 1) × (Vmax−Vth1) / 8. (N is an integer of 0 ≦ N ≦ 7), the scales 52- (7-N) to 52-8 are displayed, the remaining scales are not displayed, and the battery voltage V of the battery 11 is V ≦ V ≦ In the case of Vth1, only the scale 52-8 is displayed, and the remaining scales 52-0 to 52-7 are not displayed. That is, when the measured battery voltage of the battery 11 is the voltage Vmax, all the scales 52-0 to 52-8 are displayed, and the measured battery voltage of the battery 11 is the voltage Vth1 + 7 × (Vmax−Vth1) / 8. When the voltage is lower, the scales 52-0 to 52-7 are not displayed step by step each time the voltage value decreases. When the measured battery voltage of the battery 11 falls below the voltage Vth1, only the scale 52-8 is displayed.

  When the battery remaining amount is notified by the notification unit 15 in this way, the control signal indicating the battery remaining amount given from the signal processing unit 14 to the notification unit 15 is composed of, for example, nine types of 4-bit codes. In addition, the arithmetic circuit in the notification unit 15 can be simplified by assigning each code to the display number of the scales 52-0 to 52-8. That is, when the battery voltage V of the battery 11 is Vth1 + N × (Vmax−Vth1) / 8 <V ≦ Vth1 + (N + 1) × (Vmax−Vth1) / 8, a 3-bit code representing N in a binary number When the control signal composed of a 4-bit code with “0” added to “0” is given to the notification unit 15 and the battery voltage V of the battery 11 is V ≦ Vth1, 4 bits that are “1111” Is supplied to the control unit 15.

  When the measured battery voltage of the battery 11 is lower than the voltage Vth1, the notification unit 15 not only displays the scale 52-8 on the display unit 52 but also indicates that the battery needs to be replaced. This notification may be performed. Further, when the measured battery voltage V of the battery 11 is Vth1 <V ≦ Vth2, as described above, the signal processing unit 14 instructs the notification unit 15 to perform preliminary notification. Also good. At this time, in addition to the control signal for notifying the battery remaining amount from the signal processing unit 14 to the notification unit 15, a control signal for performing preliminary notification may be given. The necessity of preliminary notification may be determined based on a control signal indicating the remaining battery level provided from the signal processing unit 14.

  Further, when the battery voltage of the battery 11 falls below the voltage Vth1 when performing the battery remaining amount detection operation as described above, the notification unit 15 also displays this notification, and is displayed on the display unit 52. The graduation may be only the graduations 52-0 to 52-7. That is, when the measured battery voltage of the battery 11 is larger than the voltage Vth1, the remaining battery level is displayed by the scales 52-0 to 52-7 on the display unit 52, and the measured battery voltage of the battery 11 is measured. Is lower than the voltage Vth1, there is no display on the display unit 52 by the scales 52-0 to 52-7, and only the notification is performed from the notification unit 15.

  As for the notification of the remaining battery level by the notification unit 15, in addition to the scale display on the display unit 52, for example, the percentage of the remaining battery level of the battery 11, the time when the battery 11 becomes the battery life, etc. are displayed on the display unit 52. It may be displayed. In addition to the display unit 52, the light emitting unit 53 notifies the remaining battery level by changing the color and brightness of light or the blinking or lighting pattern of the light according to the remaining battery level of the battery 11. It is good also as what to do. Furthermore, when the sounding body 51 is a buzzer, the battery remaining amount may be notified by changing the cycle and duty of the buzzer sound from the sounding body 51 according to the battery remaining amount of the battery 11. . When the sounding body 51 is a speaker, the sounding body 51 may output a sound such as a percentage of the remaining battery capacity of the battery 11 or a time when the battery 11 has reached the battery life.

<Second Embodiment>
An alarm device according to a second embodiment of the present invention will be described with reference to the drawings. In addition, the structure of the alarm device of this embodiment is the same structure as the alarm device of 1st Embodiment. That is, the alarm device of the present embodiment has the internal configuration shown in the block diagram of FIG. 1 and the device configuration shown in the schematic external view of FIG.

  Since this embodiment differs from the first embodiment in the battery remaining amount notification operation in the notification unit 15 of the alarm device 1, the battery remaining amount notification operation will be described below with reference to FIG. . FIG. 5 is a diagram illustrating a relationship between the battery remaining amount display on the display unit 52 and the battery voltage of the battery 11. Also in this embodiment, as an example of the battery remaining amount notification operation, the display by the scales 52-0 to 52-8 on the display unit 52 will be described as an example, but the relationship between the battery voltage and the notification pattern is as follows. It may be the same as the relationship described below, and may be notified by the sound generator 51 or the light emitting unit 53.

  When the operation switch 16 receives a command for detecting the remaining battery level, the signal processing unit 14 drives the voltage detection unit 13 and receives a measurement signal from the voltage detection unit 13 in order to detect the remaining battery level. . Then, as in the example of the first embodiment, the signal processing unit 14 that has received the measurement signal from the voltage detection unit 13 calculates the remaining battery level based on the battery voltage of the battery 11 that is confirmed from this measurement signal. The number of scales on the scales 52-0 to 52-8 displayed on the display unit 52 of the notification unit 15 is determined. At this time, unlike the first embodiment, the display unit 52 to which the control signal is given by the signal processing unit 14 is a scale when the battery voltage V of the battery 11 satisfies Vth2 (= Vth2-0) <V ≦ Vmax. All of 52-0 to 52-8 are displayed.

  The battery voltage V of the battery 11 is Vth1 + M × (Vth2−Vth1) / 7 (= Vth2− (7−M)) <V ≦ Vth1 + (M + 1) × (Vth2−Vth1) / 7 (= Vth2− (6 −M)) (M is an integer of 0 ≦ M ≦ 6), the scale 52-0 is not displayed, the scales 52- (7-M) to 52-8 are displayed, and the remaining Hide the scale. Further, as in the first embodiment, when the battery voltage V of the battery 11 satisfies V ≦ Vth1, only the scale 52-8 is displayed, and the remaining scales 52-0 to 52-7 are not displayed. That is, when the measured battery voltage of the battery 11 is higher than the voltage Vth2, all the scales 52-0 to 52-8 are displayed. When the measured battery voltage of the battery 11 is lower than the voltage Vth2, the voltage value is Each time the level is lowered, the scales 52-0 to 52-7 are gradually hidden. When the measured battery voltage of the battery 11 falls below the voltage Vth1, only the scale 52-8 is displayed.

  Thus, in this embodiment, all the scales 52-0 to 52-8 are displayed until the battery voltage of the battery 11 falls below the threshold voltage Vth2 for performing preliminary notification, and the battery voltage of the battery 11 indicates the threshold voltage Vth2. Only when it falls below, a control signal is given from the signal processing unit 14 to the notification unit 15 so that the scale 52-0 is not displayed. Therefore, the notification unit 15 is instructed by the control signal given from the signal processing unit 14 to perform preliminary notification of battery exhaustion when it is confirmed that the scale 52-0 is not displayed and the scale 52-8 is displayed. Can be judged.

  As for the main notification of battery exhaustion, as in the first embodiment, the notification unit 15 confirms that the scale 52-8 is not displayed based on the control signal from the signal processing unit 14. It can be determined that an instruction to that effect has been made. Furthermore, also in this embodiment, when performing the detection operation of the remaining battery level, when the notification unit 15 also performs this notification when the battery voltage of the battery 11 falls below the voltage Vth1, the display unit 52 The displayed scale may be only the scales 52-0 to 52-7.

<Third Embodiment>
An alarm device according to a third embodiment of the present invention will be described with reference to the drawings. In addition, the structure of the alarm device of this embodiment is the same structure as the alarm device of 1st and 2nd embodiment. That is, the alarm device of the present embodiment has the internal configuration shown in the block diagram of FIG. 1 and the device configuration shown in the schematic external view of FIG.

  Unlike the first and second embodiments, the present embodiment is based on the measured battery voltage of the battery 11 and the next battery voltage measurement timing when the battery voltage of the battery 11 is not lower than the threshold voltage Vth1. The measurement timing for detecting battery exhaustion is set to be variable according to the battery voltage. Since the other functions and configurations are the same as those in the first or second embodiment, the battery exhaustion and remaining battery capacity notification operation, which is a feature of this embodiment, will be described below with reference to the flowchart of FIG. I will explain.

  When the power of the alarm device 1 is turned on and the power supply by the battery 11 is started, the signal processing unit 14 drives the timer 17 to start time measurement by the timer 17 (S101), and then the timer 17 Based on the measured time, it is confirmed whether or not the measurement time of the battery voltage of the battery 11 is reached (S102). At this time, if it is not the measurement timing of the battery voltage of the battery 11 (No in S102), the signal processing unit 14 confirms whether or not a command for detecting the remaining battery capacity is received by the operation switch 16 (S103).

  If the operation switch 16 is not operated (No in S103), the signal processing unit 14 is in a standby state, and whether or not the battery voltage measurement timing is based on the measurement time by the timer 17. Is confirmed (S102). On the other hand, when the operation switch 16 confirms that the battery remaining amount detection operation command has been received (Yes in S103), the signal processing unit 14 drives the voltage detection unit 13 and receives the measurement signal from the voltage detection unit 13. (S104). The signal processing unit 14 that has received the measurement signal from the voltage detection unit 13 calculates the remaining battery level based on the battery voltage of the battery 11 that is confirmed from the measurement signal, and the battery voltage of the battery 11 and the threshold voltage Vth1. Are compared (S105).

  At this time, if the battery voltage of the battery 11 is higher than the threshold voltage Vth1 (No in S105), it is determined that the battery 11 is not out of battery, so that the signal processing unit according to the command received by the operation switch 16 14 gives a control signal based on the calculated remaining battery level to the notification unit 15, and the notification unit 15 notifies the remaining battery level (S106). At this time, when the battery remaining amount is notified by the notification unit 15, any method of the first and second embodiments may be used. The signal processing unit 14 sets the time until the next battery voltage measurement timing of the battery 11 based on the calculated remaining battery level (S107), and then proceeds to operation step S102.

  That is, when the signal processing unit 14 confirms that the battery capacity of the battery 11 is greater than the calculated remaining battery capacity by performing the operation in the operation step S107, the time until the next measurement timing is set to the current set time. Set longer. On the other hand, when it is confirmed that the battery capacity of the battery 11 is less than the calculated battery remaining amount, the time until the next measurement timing is set shorter than the current set time. Thereby, the measurement timing of the battery voltage for detecting whether or not the battery is exhausted can be optimized according to the remaining battery level. In other words, when the remaining battery level is sufficient, by increasing the battery voltage measurement interval, power consumption for detecting whether or not the battery is dead can be suppressed, and the power consumption of the alarm device 1 can be reduced. Can be planned.

  When the signal processing unit 14 confirms that the measurement timing of the battery voltage of the battery 11 is based on the measurement time of the timer 17 (Yes in S102), the signal processing unit 14 detects the voltage detection unit 13 as in the operation step S104. And receives a measurement signal from the voltage detector 13 (S108). Then, similarly to the operation step S105, the signal processing unit 14 confirms the battery voltage of the battery 11 based on the measurement signal received from the voltage detection unit 13, and then compares the battery voltage of the battery 11 with the threshold voltage Vth1 (S109). .

  At this time, if the battery voltage of the battery 11 is higher than the threshold voltage Vth1 (No in S109), the signal processing unit 14 determines that the battery 11 is not out of battery, and the battery of the battery 11 confirmed from the measurement signal. After calculating the remaining battery level based on the voltage (S110), the time measured by the timer 17 is reset (S111). In this case, as described in the first embodiment, the measured battery voltage of the battery 11 is also compared with the threshold voltage Vth2, and it is confirmed that the voltage is lower than the threshold voltage Vth2. The unit 15 may perform preliminary notification that the battery has run out. Furthermore, the battery remaining amount calculated based on the battery voltage of the battery 11 confirmed from the measurement signal may be notified from the notification unit 15.

  When the signal processing unit 14 resets the timer 17 in the operation step S111, the process proceeds to the operation step 107, and until the next measurement timing of the battery voltage of the battery 11 based on the remaining battery level calculated in the operation step S110. Set the time. When the signal processing unit 14 confirms that the battery voltage of the battery 11 is lower than the threshold voltage Vth1 (Yes in S105 or S109), the signal processing unit 14 determines that the battery 11 has run out of battery, and notifies the notification unit 15 Then, a control signal is transmitted so as to perform the main notification that the battery has run out (S112). As a result, the notification unit 15 performs a notification that the battery has run out, such as a request to replace the battery 11.

<Fourth Embodiment>
An alarm device according to a fourth embodiment of the present invention will be described with reference to the drawings. FIG. 7 is a block diagram showing the internal configuration of the alarm device of the present embodiment. In the alarm device of FIG. 7, the same components as those in the alarm device of FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.

  The alarm device 1a of the present embodiment includes a supply current amount switching unit 18 configured by a resistor R and an npn-type transistor Tr in addition to the configuration of the alarm device 1 (see FIG. 1) in the first to third embodiments. Further, the configuration is added. That is, the alarm device 1a is configured to include R having one end connected to the positive electrode of the battery 11 and a transistor Tr having a collector connected to the other end of the resistor R and an emitter connected to the negative electrode of the battery 11. A current amount switching unit 18 is provided. Then, the drive of the supply current amount switching unit 18 is controlled by the signal processing unit 14 by giving the drive signal from the signal processing unit 14 to the base of the transistor Tr. Except for the configuration in which the supply current amount switching unit 18 is added, the configuration is the same as that of the above-described alarm device 1 (see FIG. 1), and the operation thereof is the same as that of the alarm device 1 of the first to third embodiments. In order to perform the same operation, the operation of the supply current amount switching unit 18 will be described in detail below.

  The supply current amount switching unit 18 is connected to the base of the transistor Tr from the signal processing circuit 14, so that the transistor Tr is turned on so that the resistor R is connected to the battery 11 with the alarm device 1 a. It is connected in parallel to each circuit that is always operating. That is, by driving the supply current amount switching unit 18, the load on the battery 11 of the entire alarm device 1a varies. Therefore, when the voltage detection unit 13 is driven and the battery voltage of the battery 11 is measured, the current amount supplied from the battery 11 to the full load of the alarm device 1a by turning on the supply current amount switching unit 18. Becomes larger.

  Therefore, when the battery voltage decreases and approaches the threshold voltage Vth1, the battery voltage of the battery 11 further decreases due to the amount of current flowing to the supply current amount switching unit 18. Thereby, for example, first, the battery voltage of the battery 11 is measured by the voltage detection unit 13 with the supply current amount switching unit 18 turned off, and the battery voltage of the battery 11 based on the measurement signal falls below the threshold voltage Vth2. When the signal processing unit 14 confirms this, the supply current amount switching unit 18 may be turned on. That is, when the battery voltage of the battery 11 falls below the threshold voltage Vth2, the supply current amount switching unit 18 is turned on in order to confirm the remaining battery level more accurately, and the battery voltage of the battery 11 is Measure again. When the measured battery voltage of the battery 11 further decreases, the signal processing unit 14 can confirm that the remaining battery level is low.

  Further, the signal processing unit 14 can detect the amount of fluctuation in the battery voltage of the battery 11 by measuring the battery voltage of the battery 11 when the supply current amount switching unit 18 is switched ON / OFF by the voltage detection unit 13. . Accordingly, the signal processing unit 14 determines the remaining battery level based on the battery voltage when the supply current switching unit 18 is OFF and the fluctuation amount of the battery 11 changed by the ON / OFF switching of the supply current switching unit 18. Can be calculated more precisely. That is, when the amount of fluctuation of the battery voltage of the battery 11 is large, it can be determined that the battery 11 is greatly affected by the load fluctuation. Therefore, the remaining battery level based on the battery voltage when the supply current switching unit 18 is OFF is further increased. Calculate with less.

  As described above, in this embodiment, the supply current amount switching unit 18 is added, and when the battery voltage of the battery 11 is measured by the voltage detection unit 13, the supply current amount switching unit 18 is operated. In the signal processing unit 14, a more accurate remaining battery level can be calculated. Further, not only when calculating the remaining battery level but also when determining whether the battery has run out, the signal processing unit 14 can more accurately determine whether the battery has run out by operating the supply current amount switching unit 18. Can be done.

  The present invention is also applicable to a fire alarm device that notifies a fire alarm by detecting smoke or heat, a gas sensor alarm device that notifies a gas alarm, and a human body detection alarm device that detects a human body. Can do.

These are block diagrams which show the internal structure of the alarm device of the 1st Embodiment of this invention. FIG. 2 is a schematic external view showing the configuration of the alarm device shown in FIG. 1. These are figures which show roughly the change of the battery voltage with respect to discharge time. These are figures which show the relationship between the display of the battery remaining charge in the display part in the alarm device of the 1st Embodiment of this invention, and the battery voltage of a battery. These are figures which show the relationship between the display of the battery remaining charge in the display part in the alarm device of the 2nd Embodiment of this invention, and the battery voltage of a battery. These are the flowcharts which show the alerting | reporting operation | movement of a battery exhaustion in the alarm device of the 3rd Embodiment of this invention. These are block diagrams which show the internal structure of the alarm device of the 4th Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,1a Alarm 11 Battery 12 Detection part 13 Voltage detection part 14 Signal processing part 15 Notification part 16 Operation switch 17 Timer 18 Supply current amount switching part 51 Sounding body 52 Display part 53 Light emission part

Claims (2)

A voltage detection unit for detecting a battery voltage; a signal processing unit for determining whether the battery has run out based on the battery voltage detected by the voltage detection unit; A battery-operated alarm device comprising:
An operation switch for receiving a battery remaining amount detection operation command; and a supply current amount switching unit for increasing the amount of current supplied from the battery to the alarm device body,
The signal processing unit stores a plurality of threshold values for determining battery exhaustion,
While switching the plurality of thresholds for each predetermined timing and comparing the battery voltage detected by the voltage detection unit to determine whether the battery has run out,
Based on the amount of change in the battery voltage when the supply current switching unit is driven to change to the state in which the amount of current supplied from the battery is increased from the state in which the supply current amount switching unit is not driven. Are detected at the same time, and this confirms that the remaining battery level is low, change the timing for determining whether the battery has run out to a shorter time interval,
When the operation switch receives a command for detecting the remaining battery level, the notification unit notifies the remaining battery level,
The notification by the notification unit changes stepwise according to the remaining battery level . In claim 1,
The alarm device further comprising a function as a test operation switch for receiving a command of a test operation for confirming the operation of the main body.

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