JP2009122967A - Bathing monitoring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To precisely obtain biological information on health condition of a person who takes a bath. <P>SOLUTION: A bathing monitoring system 10 is a system for monitoring the health condition or motion status of the person 20 who takes a bath in a bathroom. The bathing monitoring system includes a sensor unit 40 provided in a bathtub 30 and a control unit 50 provided outside the bathroom to receive an oscillation detecting signal detected by the sensor unit 40 and decide an abnormal condition, and inform about the abnormality when the abnormal condition is decided. The sensor unit 40 includes, a portable terminal 42 communicating with the control unit 50 and oscillation detecting means 46 connected to the portable terminal 42 through a cable 44. The oscillation detecting means 46 is floated on warm water in the bathtub 30 to detect an oscillation without contact by using an effect that the oscillation by the biological information of the person 20 who takes a bath is transmitted to the warm water. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a bathing monitoring system, and more particularly to a bathing monitoring system that monitors the presence or absence of abnormalities associated with changes in the physical condition of bathers in a bathroom.

  In recent years, many accidents in the bathroom due to poor physical condition such as falls during bathing, myocardial infarction, and cerebral infarction have been reported as unexpected accidents in the home. In addition, since the bathroom is a closed room, there is a known problem that accident detection is likely to be delayed, and that once an accident occurs, serious damage is likely to occur. In order to prevent such accidents during bathing, or to encourage the discovery of accidents, monitoring devices and monitoring systems that monitor the state of bathers in the bathroom and issue an alarm if an emergency occurs Many have been proposed.

  For example, the bathing monitoring system described in Patent Literature 1 floats a housing in which an acceleration sensor is housed in a bathtub, measures the ripples of the hot water surface in the bathtub generated by the bather's action, and the waves are quiet. If the state continues for a predetermined period, the bather is regarded as not active and an alarm is issued.

In addition, the health condition monitoring device described in Patent Document 2 detects biological data such as a bather's heartbeat by the sensor by contacting a part of the body of the bather with a sensor disposed in the bathtub, Based on this biometric data, the health status of the bather is judged, and when there is a danger, an alarm is issued to prompt the bather to get out of the bathtub.
JP 2007-133659 A JP 2003-70756 A

  According to the bathing monitoring system described in the above cited document 1, unnecessary warnings are frequently issued, for example, in the case of a bather who originally prefers to be quietly in the bathtub. Also, for example, even if the bather is struggling due to poor physical condition for some reason, there is a possibility that an alarm will not be issued if the ripples on the hot water surface are measured. Thus, it is difficult to accurately determine the state of the bather only by the presence or absence of the hot water surface due to the operation.

  Moreover, according to the monitoring apparatus described in the cited document 2, the health condition of the bather can be confirmed with high accuracy based on the biological data of the bather. However, in order to detect the bather's biological data, a part of the bather's body needs to be in contact with the sensor. Therefore, there is a problem that the bather's behavior is restricted, such as the bather cannot move freely in the bathtub.

  Then, in view of the said situation, this invention aims at providing the bathing monitoring system which solved the said subject.

  In order to solve the above problems, the present invention has the following means.

  (1) The present invention is a vibration detection means that is arranged so as to be in contact with hot water in a bathtub and detects vibrations of hot water, and biological information that acquires biological information of a bather from vibration signals detected by the vibration detection means. An acquisition means; a determination means for determining whether the bather's state is normal or abnormal based on the biological information acquired by the biological information acquisition means; and an alarm is issued when the determination means determines an abnormal situation The above-mentioned problem is solved by providing an alarm means.

  (2) The present invention is the bathing monitoring system according to claim 1, wherein the vibration detecting means is accommodated in a movable casing having a waterproof structure, thereby solving the above-mentioned problem. It is.

  (3) The present invention is the bathing monitoring system according to claim 2, wherein the casing includes buoyancy generating means for generating buoyancy so as to float on the surface of the hot water in the bathtub, and the vibration. A detection means solves the said subject by measuring the vibration of hot water in the state where the said housing floated on the liquid level of the hot water in the said bathtub.

  (4) The present invention is the bathing monitoring system according to claim 2, wherein the housing includes buoyancy generating means for generating buoyancy so as to float in the hot water in the bathtub, and the vibration. A detection means solves the said subject by measuring the vibration of the hot water in the state where the said housing was submerged in the liquid of the hot water in the said bathtub.

  (5) The present invention is the bathing monitoring system according to claim 2, wherein the vibration detecting means is disposed on a wall surface of a bathtub in which hot water is stored and measures vibrations of the hot water. Is a solution.

  (6) The present invention is the bathing monitoring system according to any one of claims 1 to 5, wherein the vibration detecting means detects an acceleration due to vibration propagating in the bathtub or hot water in the bathtub. Thus, the above-described problem is solved.

  (7) The present invention is the bathing monitoring system according to any one of claims 1 to 5, wherein the vibration detection means is a microphone that detects vibration caused by sound waves propagating in the bathtub or hot water in the bathtub. The present invention solves the above problems.

  (8) The present invention is the bathing monitoring system according to any one of claims 1 to 6, wherein the housing contains wireless communication means for performing wireless communication with the outside of the housing. Thus, the above-mentioned problem is solved.

  (9) The bathing monitoring system according to claim 8, wherein the alarm means transmits an alarm signal via the wireless communication means when the determination means determines that an abnormal situation has occurred. The present invention solves the above-mentioned problem by including a generating unit and a notifying unit that issues an alarm by the alarm signal generated by the alarm signal generating unit.

  (10) The bathing monitoring system according to claim 9, wherein the notification means is provided outside the bathroom and includes at least one of a speaker that emits an alarm sound and a warning light that flashes light. By having, it solves the said subject.

  (11) The present invention is the bathing monitoring system according to any one of claims 2 to 5, wherein the casing includes a rechargeable battery inside, and the rechargeable battery is not externally attached to the casing. The above-described problems are solved by being charged by contact.

  (12) According to the present invention, in the bathing monitoring system according to claim 11, when the bather does not bathe, the casing is placed on a mounting table having a charging device, and the rechargeable battery is The problem is solved by being charged by the charging device.

  (13) According to the present invention, in the bathing monitoring system according to claim 1, the determination means is abnormal when the acceleration of vibration detected by the vibration detection means is greater than or equal to a preset threshold value. The above problem is solved by judging the situation.

  (14) According to the present invention, in the bathing monitoring system according to any one of claims 1 to 6, the biological signal acquisition unit has a predetermined frequency from the vibration detection signal output from the vibration detection unit. It is a filter for extracting a component, and the filter solves the above problem by separately generating signals corresponding to the heartbeat, breathing, and body movement of the bather.

  (15) The bathing monitoring system according to (14), wherein the determination means is preset with signals corresponding to heartbeat, breathing, and body movement of the bather generated by the filter. If the value is equal to or greater than the threshold value, it is determined that the situation is abnormal, thereby solving the above problem.

  (16) The bathing monitoring system according to claim 14 or 15, wherein the filter generates a signal corresponding to a heartbeat of the bather from the vibration detection signal output from the vibration detection means. A first band filter for generating a signal corresponding to the breathing of the bather from the vibration detection signal output from the vibration detection means, and the vibration detection signal output from the vibration detection means. The above-mentioned problem is solved by having a third band filter that generates a body movement signal of the bather.

  (17) The present invention is the bathing monitoring system according to claim 9, wherein the alarm means cancels the generation of the alarm by operating a reset switch installed outside the bathroom, The present invention solves the above problems.

  (18) The present invention provides the bathing monitoring system according to claim 9, wherein the alarm means transmits abnormality occurrence information in the bathroom to a management center that manages information from each home via a public line. By doing so, the above-described problems are solved.

  (19) The bathing monitoring system according to claim 9, wherein the housing includes a response switch that outputs a response signal to an alarm generated by the alarm means, and the response switch The above-mentioned problem is solved by transmitting a response signal via the wireless communication means by operating.

  According to the bathing monitoring system according to the present invention, vibrations of the hot water in the bathtub are measured by the vibration detection means, and the biological information of the bather propagated through the hot water in the bathtub is obtained from the vibration signal. Based on the biological information, the state of the bather is judged to determine whether there is an abnormal situation and an alarm is issued, so the bather's biological information is acquired without restricting the bather's behavior in the bathtub, and this Based on the biological information, it becomes possible to accurately determine the state of the bather.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  FIG. 1 is a system configuration diagram showing a bathing monitoring system according to Embodiment 1 of the present invention. As shown in FIG. 1, a bathing monitoring system 10 is a system that monitors the physical condition or operating state of a bather 20 in a bathroom, and includes a sensor unit 40 installed in a bathtub 30 and a sensor unit provided outside the bathroom. And a control unit 50 that receives the vibration detection signal detected by 40, determines the presence / absence of an abnormality, and reports the abnormality.

  The sensor unit 40 includes a mobile terminal 42 that communicates with the control unit 50 and vibration detection means 46 connected to the mobile terminal 42 via a cable 44 as will be described later.

  The vibration detection means 46 detects vibrations of hot water in the bathtub, and measures the magnitude (amplitude) of vibrations of the hot water in the uniaxial or multiaxial directions. The vibration of the hot water in the bathtub is a vibration that includes biological information emitted from the body surface of the bather in the bathtub, that is, the heartbeat due to the heartbeat of the bather, the vibration related to the pulse, the contraction of the lungs, It includes vibrations related to breathing due to expansion, vibrations related to bather's movements, and noise from inside and outside the bathtub. The vibration detecting means 46 converts such hot water vibration into a signal such as a voltage (hereinafter referred to as “vibration detection signal”) and outputs it.

  As the vibration detection means 46, for example, an acceleration sensor or a vibration sensor that is arranged so as to be in contact with the hot water in the bathtub 30 and detects the vibration of the hot water is applied. As the acceleration sensor, for example, a piezoelectric type using a piezoelectric element, a capacitance type using a capacitor, a piezoresistive type using a piezoresistor, a gyro sensor, or a combination thereof Is applicable. Further, as the vibration sensor, a microphone using electromagnetic induction, a capacitor using a capacitor, a sensor using a piezoelectric effect, or the like can be applied.

  In the present embodiment, the vibration detection means 46 of the sensor unit 40 detects in a non-contact manner by utilizing the fact that the vibration due to the biological information of the bather 20 propagates to the hot water in the bathtub 30.

  The mobile terminal 42 of the sensor unit 40 includes a wireless communication device 43 (communication unit) that transmits a vibration signal detected by the vibration detection unit 46 to the control unit 50. The wireless communication device 43 is composed of an electronic circuit having a function of modulating a vibration signal input from the vibration detection means 46 and transmitting it wirelessly. The wireless communication device 43 may include an amplifier that amplifies the vibration signal, an A / D converter that converts an analog signal into a digital signal, an encoder that encodes a signal, and the like.

  The control unit 50 is disposed outside the bathroom, for example, in the vicinity of the bathroom entrance such as a dressing room adjacent to the bathroom, and acquires the bather's biological information from the vibration signal detected by the vibration detection means 46, and the biological information Based on the status of the bather, an alarm signal is transmitted when an abnormal situation is determined.

  Further, the control unit 50 obtains the biological information of the bather 20 from the vibration signal detected by the vibration detection means 46, and the bather 20 based on the biological information acquired by the biological information acquisition means. A determination unit configured to determine whether the state is normal or abnormal; and an alarm unit configured to issue an alarm when the determination unit determines that an abnormal situation has occurred. The alarm means may be installed in a place away from the control unit 50 (for example, a living room where a family gathers or a kitchen).

  The alarm means includes an alarm signal generating means for generating an alarm signal when the bather 20 determines that an abnormal situation has occurred, and an informing means for issuing an alarm using the alarm signal generated by the alarm signal generating means.

  Further, the control unit 50 is also equipped with a wireless communication device that transmits and receives wireless signals to and from the sensor unit 40. Further, when the control unit 50 determines that the bather 20 has an abnormality in the state where the external transmission mode set when the bather 20 lives alone is set, the public line (telephone line) 60 is used. And means for transmitting an alarm signal to the management computer 70 of the management sensor.

  The control unit 50 is connected to a charging device 80 that charges a rechargeable battery built in the portable terminal 42 when the bather 20 does not take a bath. Since the charging device 80 is provided near the entrance of the bathroom, the bather 20 enters the bathroom with the sensor unit 40 having been charged. Note that the rechargeable battery 90 (see FIG. 2) of the portable terminal 42 does not run out of battery even if the bathing is performed 4 to 5 times when the time required for bathing is 30 minutes, for example. In order to prevent the battery from running out, it is desirable to charge with the charging device 80 every time bathing is completed.

  The rechargeable battery 90 supplies electric power to each electronic device such as the vibration detection unit 46 and the wireless communication device 43. For the rechargeable battery 90, for example, a secondary battery such as a nickel metal hydride battery or a lithium ion battery can be applied. Furthermore, it is configured to be able to be charged in a non-contact manner by electromagnetic induction or the like, and is charged in a state of being housed in the casing of the portable terminal 42. Therefore, the casing of the portable terminal 42 can be kept waterproof.

  FIG. 2 is a block diagram showing the configuration of the sensor unit 40. As shown in FIG. 2, the sensor unit 40 includes a sub-control circuit 41, a wireless communication device 43 provided in the mobile terminal 42, a response switch 45, vibration detection means 46, a light receiving sensor 47, a warning buzzer 48, and a warning lamp 49. And a rechargeable battery 90.

  The wireless communication device 43 is a communication unit that performs wireless communication with the control unit 50 using weak radio waves or short-range radio. Therefore, the portable terminal 42 can be installed at any position of the bathtub 30 away from the control unit 50, and is attached to an arbitrary position according to the sitting position and posture of the bather 20. Moreover, the vibration detection means 46 can float the surface of the hot water in the bathtub 30 although it is connected to the portable terminal 42 via the extendable cable 44.

  In the present embodiment, the vibration detecting means 46 includes an acceleration sensor 46a that detects vibration propagating in hot water in a spherical waterproof case (housing) 46c having a waterproof structure, and a microphone 46b that detects sound. This will be described below as a configuration in which the Moreover, since the inside of the waterproof case 46c which forms the sealed housing is filled with air, it also functions as buoyancy generating means for generating buoyancy against hot water.

  The acceleration sensor 46a is a vibration detection means for detecting the magnitude of hot water waves, the heart movement of the bather 20, the movement of the lungs, or the acceleration of the vibration that propagates when the bather 20 moves the limb. The microphone 46b is a vibration detection unit that detects the movement of the heart of the bather 20, the movement of the lungs, or the sound generated when the bather 20 moves his limbs (vibration sound propagating in hot water). The acceleration sensor 46a is suitable for detecting vibrations having a relatively large amplitude, and the microphone 46b is suitable for detecting vibrations having a relatively small amplitude.

  The portable terminal 42 is provided with a light receiving sensor 47 on the upper surface, and switches to an operating state when it is detected that the bathroom lighting is turned on. Moreover, the response switch 45 is arrange | positioned at the front surface of the portable terminal 42, and when the response switch 45 is pressed, it is comprised so that it may switch to an operation state.

  FIG. 3 is a block diagram showing the configuration of the control unit 50. As shown in FIG. 3, the control unit 50 includes a main control circuit 51, a wireless communication device 52, a liquid crystal monitor 53, a power switch 54, a reset switch 55, a mode change switch 56, an abnormality warning lamp 57, a speaker 58, a public line. A communication modem 62 connected to 60, a memory (storage means) 64, and a power supply circuit 66 are included. The control unit 50 is connected to a charging device 80 for charging the rechargeable battery 90 of the mobile terminal 42.

  The control unit 50 is a display means for displaying a signal waveform (for example, a pulse waveform) on the front surface of the apparatus or notifying an operating state (for example, no bather, sensing, bather abnormality, bather normal). A liquid crystal monitor 53 is provided. Further, a power switch 54, a reset switch 55 for releasing an alarm, a mode changeover switch 56 for switching between mode 1 when there is a family and mode 2 when there is no family, A speaker 58 is provided for voice guidance of a preliminary warning, an alarm sound when an abnormality occurs, or an operation method.

  Further, an upper part of the control unit 50 is provided with a wireless communication device 52 and an abnormality warning lamp 57 that blinks and notifies when an abnormality is determined.

  FIG. 4 is a block diagram schematically showing the configuration of the main control circuit 51. As shown in FIG. 4, the main control circuit 51 includes an amplifier circuit 100, a biological information acquisition unit 110, a determination unit 120, an alarm signal generation unit 130, and a notification unit 140.

  The amplifying circuit 100 amplifies the vibration detection signals (acceleration signal and sound signal propagating in hot water) received from the acceleration sensor 46 a and the microphone 46 b received by the wireless communication device 52, and outputs them to the biological information acquisition unit 110.

  The biological information acquisition unit 110 is a bandpass filter that acquires a biological information signal having a predetermined frequency corresponding to the heartbeat, respiration, and bather's actions from the vibration detection signal amplified by the amplifier circuit 100, and acquires the heartbeat signal. It has the 1st band filter circuit 112, the 2nd band filter circuit 114 which acquires a respiratory signal, and the 3rd band filter circuit 116 which acquires the operation signal corresponding to the operation of the bather 20.

  The first band filter circuit 112 is a filter for separating and generating a frequency band (for example, 0.05 Hz to 2 Hz) including a heartbeat signal from the vibration detection signal, for example. The second band filter circuit 114 is a filter for separating and generating a frequency band (for example, 0.01 Hz to 0.5 Hz) including a respiratory signal from the vibration detection signal, for example. The third band filter circuit 116 is, for example, a filter for separating and generating a frequency band (for example, 0.1 Hz to 1 kHz) including the operation signal of the bather 20 from the vibration detection signal.

  The determination unit 120 is a control program that determines whether the bather 20 is in a normal state or an abnormal state based on the biological information acquired by the band filter circuits 112, 114, and 116 of the biological information acquisition unit 110. A heartbeat abnormality determining means 122 for determining presence / absence of abnormality, a respiratory abnormality determining means 124 for determining presence / absence of abnormality of a respiratory signal, and a bather operation abnormality determining means 126 for determining presence / absence of an abnormality of the bather 20's movement. Have.

  The alarm signal generation unit 130 is an alarm unit that generates an alarm signal for issuing an alarm when the determination unit 120 determines that an abnormal situation has occurred.

  The notification unit 140 is an output unit that issues an alarm in response to the alarm signal generated by the alarm signal generation unit 130, and includes the liquid crystal monitor 53, the abnormality warning lamp 57, and the speaker 58 described above.

  FIG. 5 is a waveform diagram showing a vibration detection signal detected when the bather operates in the bathtub. In FIG. 5, a graph 5A shows a heart rate signal generated by the first band filter circuit 112 when the bather 20 is normal in the bathtub 30, and a graph 5B is a second band when the bather 20 is normal in the bathtub 30. The respiratory signal generated by the filter circuit 114 is shown, and the graph 5C shows the bather operation signal generated by the third band filter circuit 116 when the bather 20 operates in the bathtub 30.

  Therefore, when the waveforms shown in the graphs 5A to 5C are acquired, it is possible to determine that the bather 20 is in the bathtub 30. Further, the heart rate of the bather 20 can be calculated based on the cycle T1 of the graph 5A, and the breathing state of the bather 20 can be recognized based on the cycle T2 of the graph 5B. And it becomes possible to judge that the physical condition (health state) of the bather 20 is normal from the heart rate and the breathing state of the bather 20. Moreover, since the operation signal acquired by the graph 5C has an amplitude greater than or equal to the threshold when the bather 20 operates in the bathtub 30, the bather 20 enters the bathtub 30 based on the magnitude of the amplitude. It becomes possible to determine whether or not.

  FIG. 6 is a waveform diagram showing a vibration detection signal detected when the bather does not move in the bathtub. In FIG. 5, a graph 6A shows a heart rate signal generated by the first band filter circuit 112 when the bather 20 is normal in the bathtub 30, and a graph 6B is a second band when the bather 20 is normal in the bathtub 30. The respiratory signal generated by the filter circuit 114 is shown, and the graph 6C shows the bather operation signal generated by the third band filter circuit 116 when the bather 20 does not move in the bathtub 30.

  In this case, since the waveform of the graph 6C is equal to or less than the threshold value, it is determined that the bather 20 is not moving in the bathtub 30 and the heartbeat and breathing cycle of the bather 20 is determined based on the waveforms of the graphs 6A and 6B. It is determined that T1 and T2 are normal. Therefore, when the waveforms shown in the graphs 6A to 6C are acquired, it can be seen that although the bather 20 does not move in the bathtub 30, the health condition is normal.

  FIG. 7 is a waveform diagram showing a vibration detection signal detected when the bather leaves the bathtub. In FIG. 5, a graph 7A shows a heartbeat signal generated by the first band filter circuit 112 when the bather 20 leaves the bathtub 30, and a graph 7B shows the second band when the bather 20 leaves the bathtub 30. The respiratory signal generated by the filter circuit 114 is shown, and the graph 7C shows the bather operation signal generated by the third band filter circuit 116 when the bather 20 moves out of the bathtub 30 and operates.

  In this case, the waveforms of the graphs 7A and 7B hardly change, and the heartbeat and the respiration signal are not detected. Therefore, it is determined that the bather 20 is out of the bathtub 30. In addition, it can be seen from the waveform of the graph 7C that the bather 20 is operating in the bathroom. For example, if the threshold level is 1 to 2 as in the waveform 7C1, the bather 20 can wash the hair or wash the body. It can be determined that the operation is being performed.

  Further, if the threshold level is 2 or more as in the waveform 7C2, the amplitude of the vibration detection signal is abnormally large, so that the bather 20 slips on the leg and falls in the bathroom, or the bather 20 loses balance and the bathtub 30 It can be determined that an abnormal operation such as a collision was performed. Therefore, according to the bathing monitoring system 10, the biological information of the bather 20 is acquired without restricting the behavior of the bather 20 in the bathtub 30, and the state of the bather 20 is accurately determined based on the biological information. It becomes possible to do.

  Here, the control process executed by the sub control circuit 41 of the sensor unit 40 will be described with reference to the flowchart of FIG.

  When the light receiving sensor 47 is turned on by illumination of the bathroom or the response switch 45 is turned on by the bather 20 in a state where the sub-control circuit 41 is disconnected from the charging device 80 in S11, the bather 20 enters the bathroom. In step S12, it is checked whether the acceleration sensor 46a outputs an acceleration signal (vibration detection signal). In S12, when an acceleration signal (vibration detection signal) is output from the acceleration sensor 46a (in the case of YES), the process proceeds to S13, and the acceleration signal (vibration detection signal) output from the acceleration sensor 46a is transmitted from the wireless communication device 43. To do. Thereby, the acceleration signal in the bathtub 30 detected by the acceleration sensor 46a is converted into a radio signal and received by the radio communication device 52 of the control unit 50. In S12, when an acceleration signal (vibration detection signal) is not output from the acceleration sensor 46a (in the case of NO), the process proceeds to S14.

  In next S14, it is checked whether or not the microphone 46b outputs a sound signal (vibration detection signal). In S14, when a sound signal (vibration detection signal) is output from the microphone 46b (in the case of YES), the process proceeds to S15, and the sound signal (vibration detection signal) output from the microphone 46b is transmitted from the wireless communication device 43. Thereby, the sound signal in the bathtub 30 detected by the microphone 46 b is converted into a radio signal and received by the radio communication device 52 of the control unit 50.

  In next S16, it is checked whether or not a preliminary alarm from the control unit 50 is received. In S16, when the preliminary alarm from the control unit 50 is not received (in the case of NO), the process returns to S11 and the processes of S11 to S16 are repeated.

  In S16, when a preliminary alarm is received from the control unit 50 (in the case of YES), the process proceeds to S17, a buzzer sound is generated from the warning buzzer 48, and the warning lamp 49 is flashed to the bather 20. Announce a preliminary warning. Thereby, the bather 20 operates the response switch 45 to ON when there is no abnormality.

  In the next S18, it is checked whether or not the response switch 45 has been turned on. In S18, when the response switch 45 is turned on by the bather 20, the process proceeds to S19, and a response signal is transmitted from the wireless communication device 43. If the response switch 45 is not turned on by the bather 20 in S18, the process returns to S11 and the processes of S11 to S18 are repeated. Since the control processing of S11 to S19 shown in FIG. 8 is executed in a state where the sensor unit 40 is attached to the bathtub 30, the sub-control circuit 41 is shown in FIG. 8 when charging. It is programmed not to do.

  Next, mode 1 control processing executed by the main control circuit 51 of the control unit 50 will be described with reference to the flowchart of FIG. When the mode changeover switch 56 is operated in mode 1 and the power switch 54 is turned on, the main control circuit 51 propagates the vibration detection signal transmitted from the sensor unit 40 in S21 (the hot water in the bathtub is propagated). Read acceleration signal, sound signal).

  In the next S22, a biological information signal having a predetermined frequency corresponding to the heartbeat, respiration, and bather's actions is acquired from the vibration detection signal by the biological information acquisition means 110 described above (see FIGS. 5 to 7). Subsequently, the heart rate is calculated based on the heart rate signal included in the biological information acquired in S23, and this heart rate (the number of heart motions per minute) is set to a preset upper limit value (for example, 90 times / minute). Check whether it is more than ~ 135 times / min).

  In S23, when the detected heart rate is less than the preset upper limit value (in the case of NO), the process proceeds to S24, where the heart rate is calculated based on the heart rate signal included in the acquired biological information, and this heart rate Is less than or equal to a preset lower limit (for example, 40 times / minute to 60 times / minute).

  In S24, when the heart rate is not less than or equal to the preset lower limit value (in the case of NO), the process proceeds to S25, and the respiration rate (the number of lung movements per minute) is the upper limit value (for example, 20 times / minute to 40 Check whether or not the number of times / min.

  In S25, when the respiratory rate is less than the upper limit value (in the case of NO), the process proceeds to S26, and it is checked whether or not the respiratory rate is equal to or lower than the lower limit value (for example, 10 times / minute to 15 times / minute).

  In S26, when the respiration rate is not less than or equal to the lower limit value (in the case of NO), the process proceeds to S27 and it is determined that the bather 20 is in a normal physical condition. Thereafter, the process returns to S21, and the processes after S21 are repeated.

  In S <b> 27, when the physical condition of the bather 20 is normal, the heart rate and the respiratory rate are stored in the memory 64. As a result, heart rate and respiration rate data in the case of normality can be stored in the memory 64 to create a database, and it is possible to check past and current health history histories.

  In S23, when the detected heart rate is equal to or higher than a preset upper limit value (in the case of YES), the process proceeds to S28, and the heart rate is stored in the memory 64. Thereby, the abnormal value of the heart rate of the bather 20 can be confirmed. In S29, a warning sound (for example, a sound whose volume is suppressed to be lower than that of an abnormality report) is output from the speaker 58 as a preliminary alarm, and a preliminary alarm signal is wirelessly transmitted to the sensor unit 40.

  In next S30, it is checked whether or not a response signal from the sensor unit 40 has been received. In S30, when the bather 20 operates the response switch 45 of the portable terminal 42 to turn on the warning sound (in the case of YES), it is determined that there is no abnormality in the bather 20, the process proceeds to S31, and the memory 64 Reset the data (heart rate, respiratory rate) stored in.

  In S25, when the respiration rate is equal to or higher than the upper limit (in the case of YES), the process proceeds to S32 and the respiration rate is stored in the memory 64. Thereby, the abnormal value of the respiration rate of the bather 20 can be confirmed. Thereafter, the processes of S29, S30, and S31 described above are executed.

  In S24, when the heart rate is equal to or lower than a preset lower limit value (in the case of YES), or in S26, when the respiratory rate is equal to or lower than the lower limit value (in the case of YES), the process proceeds to S33 and the acceleration sensor 46a. Alternatively, it is checked whether or not a detection signal (heartbeat, breathing, coughing, sneezing, hot water level fluctuation, etc.) accompanying the presence of the bather 20 is output by the microphone 46b.

  In S33, when a detection signal associated with the presence of the bather 20 is output by the acceleration sensor 46a or the microphone 46b (in the case of YES), it is determined that the bather 20 is in the bathtub 30, and the processes after S29 are performed.

  In S33, when the detection signal associated with the presence of the bather 20 is not output by the acceleration sensor 46a or the microphone 46b (in the case of NO), the process proceeds to S34, where it is determined that the bather 20 is outside the bathtub 30. In next S35, it is checked whether or not abnormal vibration is detected by the acceleration sensor 46a or the microphone 46b. In S35, for example, when abnormal vibration (waveform 7C2 in FIG. 7) that occurs when the bather 20 falls or slides a leg and collides with the bathtub 30 is detected (in the case of YES), The process proceeds to S29. If no abnormal vibration is detected in S35, the process proceeds to S36, where it is determined that the physical condition of the bather 20 is normal, and the process returns to S21.

  In S30, when the bather 20 does not operate the response switch 45 of the portable terminal 42 to turn on the warning sound (in the case of NO), the process proceeds to S37, and some abnormal situation has occurred in the bather 20. Judge that it is. In S38, an abnormality occurrence alarm is output, the abnormality warning lamp 57 blinks, and an alarm sound is emitted from the speaker 58 to notify the abnormality of the bather 20. Thereby, the family in a separate room can know the abnormality of the bather 20 and can immediately move to the bathroom and care for the bather 20. When the bather 20 is heavy, an ambulance can be called by reporting to the emergency center.

  In the next step S39, it is checked whether or not the reset switch 55 has been turned on. If the reset switch 55 has been turned on, the process proceeds to S40, the abnormal warning lamp 57 blinks, and the alarm sound of the speaker 58 is sounded. Stop.

  Next, mode 2 control processing executed by the main control circuit 51 of the control unit 50 will be described with reference to the flowchart of FIG. When the mode changeover switch 56 is operated to mode 2, the main control circuit 51 executes the control process of FIG. In FIG. 10, S41 to S60 are the same processes as S21 to S40 of FIG.

  In S59 of FIG. 10, when the reset switch 55 is not turned on, the process proceeds to S61, and it is checked whether or not a predetermined time (for example, 3 minutes) set in advance has elapsed. If the reset switch 55 is turned on within this predetermined time, the process proceeds to S60, and the flashing of the abnormality warning lamp 57 and the alarm sound of the speaker 58 are stopped.

  In S61, if the reset switch 55 is not turned on even after a predetermined time has passed, the process proceeds to S62, and an error has occurred in the bather 20 in the management computer 70 of the management center via the communication modem 62. report.

  FIG. 11 is a conceptual diagram for explaining an emergency information reporting system using a management computer. As shown in FIG. 11, the control unit 50 normally has a normal state of the bather 20 in the management computer 70 installed on the management center side via the public line 60 regardless of the operation position of the mode switch 56. Send data regularly (eg every week). Therefore, the control unit 50 transmits the heart rate and respiration rate data stored in the memory 64 to the management computer 70 on the management center side, so that the health status of the plurality of bathers 20 is concentrated on the management center side. It becomes possible to manage. For example, a doctor who has received data on each person's heart rate and respiration rate from the management center can periodically check the data to manage each person's health.

  When the mode changeover switch 56 is operated to mode 2, the control unit 50 is configured to use a public line 60 such as a telephone line if the reset switch 55 is not turned on even after a predetermined time has passed since the alarm was output. The abnormal state of the bather 20 is reported to the management computer 70 via

  The management computer 70 manages a plurality of control units 50 installed in each of a plurality of homes, and when an abnormality occurrence is transmitted from one control unit 50, the address of the home where the control unit 50 is installed. Information such as name and telephone number is transmitted to the host computer 74 of the emergency center via the communication modem 72 and the public line 60.

  Further, the host computer 74 of the emergency center (119) sends ambulance dispatch request information (such as the address, name, and telephone number) from the address included in the received information to the terminal 76 of the fire department near the bather 20. Information). As a result, the fire station that has received the ambulance dispatch request information moves the ambulance toward the reported address and transports the bather to the hospital.

  In the emergency information reporting system, when the management computer 70 receives the abnormal state of the bather 20 from the control unit 50, the management center operator may notify the emergency center operator via the telephone line. good.

  Further, as the public line 60, a communication line other than a telephone line (for example, the Internet) may be used.

  FIG. 12 is a system configuration diagram illustrating a bathing monitoring system according to the second embodiment. In FIG. 12, the same parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof is omitted. As shown in FIG. 12, in the bathing monitoring system 200, the vibration detection means 210 is installed in a state of being submerged in the hot water stored in the bathtub 30. In the vibration detection unit 210, an acceleration sensor 46a and a microphone 46b are housed in a waterproof case 212 having a waterproof structure. Further, on the side surface of the waterproof case 212, a vibration plate 214 is provided for receiving vibration due to heartbeat, breathing, and movement of the bather 20 propagating in hot water. The diaphragm 214 is made of, for example, an extremely thin metal plate, and has a larger pressure receiving area than the sensor in order to increase vibration detection sensitivity.

  The vibration detection means 210 detects the vibration state of the vibration plate 214 that vibrates by passing hot water with the acceleration sensor 46a and the microphone 46b, so that vibration due to the heartbeat, breathing, and movement of the bather 20 can be detected with high accuracy. It is configured.

  The vibration detection unit 210 is connected to the mobile terminal 42 via the cable 44. Then, the vibration detection signal detected by the vibration detection unit 210 is converted into a radio signal and transmitted to the control unit 50.

  In the control unit 50, as in the first embodiment described above, each biological information is extracted from the detection signal obtained from the vibration detection means 210 to determine the state of the bather 20, and if there is an abnormality, an alarm is output.

  FIG. 13 is a system configuration diagram illustrating a bathing monitoring system according to the third embodiment. In FIG. 13, the same parts as those in the first and second embodiments are denoted by the same reference numerals, and the description thereof is omitted. As shown in FIG. 13, in the bathing monitoring system 300, a plurality of vibration detection means 310 are inserted into the recesses 32 provided at a plurality of locations (at least three locations) on the inner wall of the bathtub 30. In addition, a pillow-shaped biological information detection means 320 is installed on the upper edge 34 of the bathtub 30.

  The plurality of vibration detection means 310 detects vibrations due to heartbeat, breathing, and movement of the bather 20 propagating in hot water. The living body information detection means 320 can detect not only the heartbeat of the bather 20 but also the body temperature, blood pressure, and the like by contacting the back head of the bather 20.

  The plurality of vibration detection means 310 and the biological information detection means 320 are connected to the portable terminal 42 fixed to the inner wall of the bathtub 30 via a cable 330 (shown by a broken line). The detection signals detected by the plurality of vibration detection means 310 and the biological information detection means 320 are converted into radio signals and transmitted to the control unit 50.

  In the control unit 50, as in the first embodiment described above, each biological information is extracted from the detection signals obtained from the plurality of vibration detecting means 310 and the biological information detecting means 320, and the state of the bather 20 is determined. If there is, an alarm is output.

  The bathing monitoring system 300 is installed mainly in a nursing facility or a hospital where a caregiver is waiting in the bathroom or outside the bathroom. When an abnormality occurs in the bather 20, the control unit 50 outputs an alarm to the caregiver. It is comprised so that abnormality may be alert | reported. Further, in the bathing monitoring system 300, it is possible to determine the health condition of the bather 20 by analyzing the detection signals and biological information from the plurality of vibration detection means 310 and the biological information detection means 320, and thus more accurately. It is possible to determine whether there is an abnormality.

  FIG. 14 is a system configuration diagram illustrating a bathing monitoring system according to the fourth embodiment. In FIG. 14, the same parts as those in the first, second, and third embodiments are denoted by the same reference numerals, and the description thereof is omitted. As shown in FIG. 14, the bathing monitoring system 400 includes a sensor unit 410 and the control unit 50 described above. The control unit 50 is connected to a charging device 420 that can be charged in a non-contact manner. The sensor unit 410 is placed in the placement recess 422 of the charging device 420 when bathing is not performed.

  The sensor unit 410 has a built-in rechargeable battery 90. The charging device 420 is configured to energize the primary coil when the sensor unit 410 is placed in the placement recess 422. Therefore, when the sensor unit 410 is not used, the rechargeable battery 90 is charged by generating a secondary current in the secondary coil on the battery side by electromagnetic induction of the charging device 420.

  The sensor unit 410 integrates the portable terminal of the above-described embodiment and the vibration detection means, and detects the heartbeat, breathing, and movement of the bather 20 while floating on the surface of the hot water stored in the bathtub 30. To do.

  FIG. 15 is a longitudinal sectional view of the sensor unit 410 according to the fourth embodiment. FIG. 16 is a plan view of the sensor unit 410 according to the fourth embodiment. As shown in FIGS. 15 and 16, the sensor unit 410 has a waterproof section 440 formed at the center of the inside of a waterproof case 430 formed in a disk shape. In the waterproof compartment 440, a battery storage chamber 441, a sensor storage chamber 442, a circuit storage chamber 443, and a switch storage chamber 444 are defined by each partition wall 445.

  Buoyancy generating chambers 450 and 452 are formed around the waterproof compartment 440. The buoyancy generation chambers 450 and 452 are formed in two upper and lower stages. Since the buoyancy generation chambers 450 and 452 have an airtight structure, the battery storage chamber 441, the sensor storage chamber 442, the circuit storage chamber 443, and the switch storage chamber 444 formed inside the waterproof compartment 440 are formed on a double waterproof wall. Surrounded and reliably prevented from entering hot water.

  The battery storage chamber 441 is formed at the bottom of the waterproof compartment 440, and a plurality of heavy rechargeable batteries 90 are stored therein. Since the storage position of the rechargeable battery 90 is set to a low position, the center of gravity of the sensor unit 410 has a low center of gravity due to the rechargeable battery 90. Thereby, even if the sensor unit 410 is turned upside down, it can be reversed.

  The sensor storage chamber 442 stores an acceleration sensor 46a.

  In the circuit storage chamber 443, control system components such as the sub control circuit 41 are stored.

  Each switch is stored in the switch storage chamber 444.

  A wireless communication device 43, a response switch 45, a light receiving sensor 47, a warning buzzer 48, a warning lamp 49, and a microphone 46b are provided on the upper surface side of the waterproof case 430. The response switch 45 is a push-type switch and has a larger surface area than other components so that it can be easily operated. In addition, the warning lights 49 are provided at four positions at intervals of 90 ° in the circumferential direction, and are arranged so that they can be seen from any direction of the sensor unit 410.

  An underwater microphone 470 is provided on the lower surface side of the waterproof case 430.

  Since the waterproof case 430 is floated in the hot water in the bathtub 30, the waterproof case 430 is formed of a relatively soft resin material such as rubber so as not to be injured when contacting the bather 20. A buffer member 460 is attached over the entire circumference. The buffer member 460 is made of a rubber material and has an annular shape and a semicircular cross section. The buffer member 460 cushions an impact at the time of contact with the bather 20.

  The sensor unit 410 is used in a state where it floats on the liquid level of the bathtub 30, detects the movement of the bather 20 by the acceleration sensor 46 a, and detects the breathing and heartbeat of the bather 20 by the microphone 46 b or the underwater microphone 470. can do.

  Since the arithmetic processing of the control circuit 41 of the sensor unit 410 is the same as that of the first embodiment described above, description thereof is omitted.

  In the control unit 50, as in the first embodiment described above, each biological information is extracted from the detection signal obtained from the sensor unit 410 to determine the state of the bather 20, and an alarm is output if there is an abnormality.

  As shown in FIG. 17, the sensor unit 410 can halve its buoyancy by pouring water into one of the buoyancy generation chambers 450 and 452. As a result, the sensor unit 410 can immerse 3/4 of the total volume in the water with respect to the liquid level 480 (indicated by a one-dot chain line) of the bathtub 30. In this case, it is possible to reduce the influence of waves generated on the liquid surface 280. For example, it is possible to make it difficult to detect acceleration due to waves when the hot water in the bathtub 30 is pumped. In this state, the wireless communication device 43, the response switch 45, the light receiving sensor 47, the warning buzzer 48, the warning lamp 49, and the microphone 46 b disposed on the upper surface side of the waterproof case 430 are exposed from the liquid level 480. There is no effect on operability.

  As shown in FIG. 18, when water is injected into both buoyancy generation chambers 450 and 452, the buoyancy of the sensor unit 410 is greatly reduced, and the sensor unit 410 is in the liquid level 480 of the bathtub 30 (in a two-dot chain line). Dive below) In this case, the heart rate, breathing, and body movement of the bather 20 are detected while the entire sensor unit 410 is floating in the hot water, and it is not necessary to be affected by the waves generated on the liquid level 480. .

  FIG. 19 is a longitudinal sectional view showing the sensor unit 510 of the fifth embodiment. In FIG. 19, the same parts as those in the first to fourth embodiments are denoted by the same reference numerals, and the description thereof is omitted. As shown in FIG. 19, the bathing monitoring system 500 includes a floating sensor unit 510.

  The sensor unit 510 includes a warning light 49, a light receiving sensor 47, a wireless communication device 43, a response switch 45, a float 520, a sub control circuit 41, an acceleration sensor 46b, and a rechargeable battery 90 in a cylindrical waterproof case 512 from above. The underwater microphones 470 are housed in this order. The waterproof case 512 is formed of a translucent resin material, and the inside thereof prevents contact between the components and insulates the components so as to insulate the components. (Shown with a satin pattern). Since the gaps inside the waterproof case 512 are filled with the gel material 530, the internal components are protected from hot water even if the waterproof case 512 is damaged.

  The response switch 45 is a membrane switch formed in a cylindrical shape, and is turned on by suppressing the outer periphery, and outputs a response signal.

  The float 520 is arranged above the center of the waterproof case 512, and the buoyancy is set so that the upper part 1/3 of the sensor unit 510 protrudes above the liquid level 480. Further, since the rechargeable battery 90 having a relatively large weight is accommodated at the bottom of the waterproof case 512, the sensor unit 510 has a low center of gravity structure. Therefore, the sensor unit 510 swings in an inclined state even if a wave occurs on the liquid level 480, but can return to a vertical state at any time.

  Further, since the sensor unit 510 is in a vertical state, it can sensitively detect the vertical movement of the liquid level 480, so that it can accurately detect whether or not the bather 20 has performed an abnormal operation in the bathtub 30. Can do.

  Since the sensor unit 510 and the control unit 50 have the same functions as those of the fourth embodiment described above, description thereof is omitted.

  FIG. 20 is a configuration diagram illustrating a configuration of the sensor unit 610 according to the sixth embodiment. In FIG. 20, the same parts as those in the first to fifth embodiments are denoted by the same reference numerals, and the description thereof is omitted. As shown in FIG. 20, the bathing monitoring system 600 includes a distributed sensor unit 610.

  The sensor unit 610 includes a first unit 620 floating on the liquid level 480, a second unit 630 diving in the hot water in the bathtub 30, a third unit 640 diving near the bottom of the bathtub 30, and a bottom surface of the bathtub 30. A fourth unit 650 in contact therewith. The first unit 620 and the second unit 630 are connected by a first connecting member 660 made of a flexible cable having flexibility. The second unit 630 and the third unit 640 are connected by a second connecting member 670 made of a flexible cable or the like. The third unit 640 and the fourth unit 650 are connected by a third connecting member 680 made of a flexible cable or the like.

  Each of the first unit 620, the second unit 630, the third unit 640, and the fourth unit 650 accommodates each device in a waterproof case, and each of the plurality of sensors has the same configuration as the sensor unit 410 described above. It is good also as a structure which connected the unit in 1 row.

  Alternatively, each device may be distributed in each first unit 620, second unit 630, third unit 640, and fourth unit 650. For example, the first unit 620 contains a warning light 49, a light receiving sensor 47, a wireless communication device 43, and a response switch 45, and the second unit 630 contains a sub control circuit 41 and an acceleration sensor 46b. The unit 640 may include a rechargeable battery 90 and an underwater microphone 470. The fourth unit 650 stores a weight made of a material having a high specific gravity.

1 is a system configuration diagram illustrating a bathing monitoring system according to a first embodiment of the present invention. 3 is a block diagram showing a configuration of a sensor unit 40. FIG. 2 is a block diagram showing a configuration of a control unit 50. FIG. 2 is a block diagram schematically showing a configuration of a main control circuit 51. FIG. It is a wave form diagram which shows the vibration detection signal detected when a bather operate | moves in a bathtub. It is a wave form diagram which shows the vibration detection signal detected when a bather does not move in a bathtub. It is a wave form diagram which shows the vibration detection signal detected when a bather leaves a bathtub. 4 is a flowchart for explaining a control process executed by a sub-control circuit 41. 3 is a flowchart for explaining a control process in mode 1 executed by a main control circuit 51 of a control unit 50. 4 is a flowchart for explaining a control process in mode 2 executed by a main control circuit 51 of the control unit 50. It is a conceptual diagram for demonstrating the emergency information reporting system by a management computer. It is a system block diagram which shows the bathing monitoring system of Example 2. It is a system block diagram which shows the bathing monitoring system of Example 3. It is a system block diagram which shows the bathing monitoring system of Example 4. It is a longitudinal cross-sectional view of the sensor unit 410 of Example 4. It is a top view of the sensor unit 410 of Example 4. It is a longitudinal cross-sectional view which shows the state which inject | poured water into the buoyancy generation chamber 452 of the sensor unit 410 of Example 4. FIG. It is a longitudinal cross-sectional view which shows the state which inject | poured water into the buoyancy generation chamber 450,452 of the sensor unit 410 of Example 4. FIG. FIG. 10 is a longitudinal sectional view showing a sensor unit 510 of Example 5. FIG. 10 is a configuration diagram showing a configuration of a sensor unit 610 of Example 6.

Explanation of symbols

10, 200, 300, 400, 500, 600 Bathing monitoring system 20 Bathing person 30 Bathtub 40, 410, 510, 610 Sensor unit 42 Portable terminal 41 Sub-control circuit 43, 52 Wireless communication device 45 Response switch 46, 210, 310 Vibration Detection means 46a Acceleration sensor 46b Microphone 46c Waterproof case 47 Light receiving sensor 48 Warning buzzer 49 Warning light 50 Control unit 51 Main control circuit 53 Liquid crystal monitor 54 Power switch 55 Reset switch 56 Mode change switch 57 Abnormal warning light 58 Speaker 60 Public line 64 Memory 70 Management Computer 80, 420 Charging Device 90 Rechargeable Battery 100 Amplifying Circuit 110 Biological Information Acquisition Unit 112 First Band Filter Circuit 114 Second Band Filter Circuit 116 Third Band Filter Circuit 120 Determination Means 130 Alarm signal generation means 140 Notification means 212, 430, 512 Waterproof case 320 Biological information detection means 440 Waterproof compartment 441 Battery storage chamber 442 Sensor storage chamber 443 Circuit storage chamber 444 Switch storage chamber 445 Partition 450, 452 Buoyancy generation chamber 470 Underwater Microphone 480 Liquid level 520 Float 620 First unit 630 Second unit 640 Third unit 650 Fourth unit 660 First connecting member 670 Second connecting member 680 Third connecting member

Claims (19)

A vibration detecting means arranged to contact the hot water in the bathtub and detecting the vibration of the hot water;
Biological information acquisition means for acquiring biological information of the bather from the vibration signal detected by the vibration detection means;
Determining means for determining whether the state of the bather is normal or abnormal based on the biological information acquired by the biological information acquiring means;
Alarm means for issuing an alarm when the determination means determines an abnormal situation;
A bathing monitoring system comprising:   The bathing monitoring system according to claim 1, wherein the vibration detection unit is housed in a movable casing having a waterproof structure. The housing has buoyancy generating means for generating buoyancy so as to float on the surface of the hot water in the bathtub,
The bathing monitoring system according to claim 2, wherein the vibration detecting unit measures the vibration of the hot water in a state where the casing is floated on the surface of the hot water in the bathtub. The housing has buoyancy generating means for generating buoyancy so as to float in the hot water in the bathtub,
The bathing monitoring system according to claim 2, wherein the vibration detecting unit measures the vibration of the hot water in a state where the casing is submerged in the hot water in the bathtub. The vibration detecting means is disposed on a wall surface of a bathtub in which hot water is stored,
The bathing monitoring system according to claim 2, wherein vibrations of hot water are measured.   The bathing monitoring system according to any one of claims 1 to 5, wherein the vibration detection means is an acceleration sensor that detects acceleration due to vibration propagating in the bathtub or hot water in the bathtub.   The bathing monitoring system according to any one of claims 1 to 5, wherein the vibration detection means is a microphone that detects vibration due to a sound wave propagating through the bathtub or hot water in the bathtub.   The bathing monitoring system according to any one of claims 1 to 6, wherein a wireless communication means for wirelessly communicating with the outside of the housing is accommodated in the housing. The alarm means includes
An alarm signal generating means for transmitting an alarm signal via the wireless communication means when the determining means determines an abnormal situation;
An informing means for issuing an alarm according to the alarm signal generated by the alarm signal generating means;
The bath monitoring system according to claim 8, comprising:   The bathing monitoring system according to claim 9, wherein the notification means includes at least one of a speaker that emits an alarm sound and a warning light that blinks light, provided outside the bathroom. The housing contains a rechargeable battery inside,
The bathing monitoring system according to any one of claims 2 to 5, wherein the rechargeable battery is charged in a non-contact manner from outside the casing. When the bather does not take a bath, the housing is placed on a mounting table having a charging device,
The bathing monitoring system according to claim 11, wherein the rechargeable battery is charged by the charging device.   2. The bathing monitoring system according to claim 1, wherein when the acceleration of the vibration detected by the vibration detection unit is greater than or equal to a preset threshold value, the determination unit determines that an abnormal situation has occurred. The biological signal acquisition means is a filter that extracts a predetermined frequency component from the vibration detection signal output from the vibration detection means,
The bath monitoring system according to any one of claims 1 to 6, wherein the filter separately generates signals corresponding to heartbeat, breathing, and body movement of the bather.   15. The determination unit according to claim 14, wherein when the signal corresponding to the heartbeat, breathing, and body movement of the bather generated by the filter is equal to or greater than a predetermined threshold, an abnormal situation is determined. Bathing monitoring system as described in. The filter generates a signal corresponding to the heartbeat of the bather from the vibration detection signal output from the vibration detection means;
A second band filter for generating a signal corresponding to the breathing of the bather from the vibration detection signal output from the vibration detection means;
A third band filter for generating a body movement signal of the bather from the vibration detection signal output from the vibration detection means;
The bath monitoring system according to claim 14 or 15, characterized by comprising:   The bathing monitoring system according to claim 9, wherein the alarm unit cancels the generation of the alarm by operating a reset switch installed outside the bathroom.   10. The bathing monitoring system according to claim 9, wherein the alarm means transmits abnormality occurrence information in the bathroom to a management center that manages information from each home via a public line. The housing has a response switch that outputs a response signal to an alarm generated by the alarm means,
The bathing monitoring system according to claim 9, wherein a response signal is transmitted through the wireless communication unit when the response switch is operated.

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