KR20210130501A - Sleep monitoring and sleep disorder response system - Google Patents

Abstract

The present invention relates to a system for monitoring human body information such as a position of a human body when sleeping, a movement of the human body during sleep, and heart beats in real time, and dealing with a sleep disorder by inducing a sleeper to change the position of the sleeper. The system comprises: a respiratory organ sensing unit worn on a respiratory organ of a human body to transmit results of sensing gas breathed into the respiratory organ; a human body motion sensing unit worn on the human body to transmit results of sensing a movement and a position of the human body; a human body information processing unit (300) generating a control signal for controlling a sleep state of the human body in accordance with the sensed results of the respiratory organ sensing unit or the human body motion sensing unit; and a sleep state control unit executing a motion for controlling the sleep state of the human body in accordance with the control signal from the human body information processing unit (300). The system for dealing with a sleep disorder through real-time monitoring provides the effect of inducing a sleeper to change the sleep position of the sleeper to deal with a sleep disorder such as snoring and sleep apnea syndrome and allow the sleeper to have a deep sleep.

Description

Sleep monitoring and sleep disorder response system

The present invention relates to a system for inducing changes in the posture of the sleeping person by monitoring human body information such as the posture of the human body during sleep, the movement of the human body during sleep, and heartbeat in real time, and more particularly, the sleeper's apnea or snoring. It relates to a sleep disorder response system through real-time monitoring to respond to sleep disorders by stopping them.

Snoring occurs when the throat, through which air passes before it enters the airway, becomes narrow while breathing, making it difficult for air to enter and exit easily. In general, during sleep, air passes through areas such as the roof of the mouth, uvula, tonsils, and tongue, and during the daytime, the surrounding muscles help these areas to stay in place so that the air passages are not blocked.

However, as the muscles relax and stretch during sleep, the air passage is partially narrowed, and when the air passes through this part, it vibrates the surrounding soft parts and causes snoring. In addition, if the air passage is completely blocked due to severe muscle relaxation during sleep or due to other causes such as severe obesity, sleep apnea occurs, in which air cannot flow to the lungs at all. there is a problem.

Such sleep apnea is accompanied by symptoms such as severe drowsiness and fatigue during the daytime despite sufficient sleep time by lowering the quality of sleep, as well as deterioration of memory and concentration. In addition, if these symptoms continue for a long time, it increases the burden on the heart or lungs, and can cause serious complications such as high blood pressure, heart attack, and seizures. In order to cope with sleep disorders such as snoring or sleep apnea, various methods including a pillow for preventing snoring are used, but there is a problem that the effectiveness is insignificant.

In addition, in order to continuously monitor the state of the sleeper, there is a disadvantage in that a special equipment, that is, a complicated measurement cable, is connected to the body of the sleeper, thereby disturbing sleep and making it impossible to achieve deep sleep. Since such a monitoring device has a limited operating range, it limits the movement of the sleeping person by requiring the observed sleeping person to be located close to the monitoring situation, and the monitored data contents are also checked after a certain period of time has elapsed. There is a problem in that an opportunity to take action in real time in case of an emergency may be lost as there is a delay in time, such as such.

The present invention was created to solve the above problems, and monitors or determines the sleep state of the sleeper by wirelessly transmitting the respiratory rate, electrocardiogram, posture, etc. through a measurement sensor worn on the sleeper's body, An object of the present invention is to provide a sleep disorder response system through real-time monitoring for controlling the sleep state of the sleeper.

In addition, another object of the present invention is to provide a sleep disorder response system through real-time monitoring that allows the sleeper to escape from sleep disorders by changing the posture of the sleeper by deforming the mattress of the bed according to the sleep state of the sleeper.

In addition, another object of the present invention is to monitor the human body information when the sleeping person is sleeping, and when an abnormal symptom occurs, the situation is communicated in real time to the sleeping person, guardian, and medical personnel, so that the user can prepare for an emergency in real time. It is to provide a sleep disorder response system through

In order to achieve the above object, the sleep disorder response system through real-time monitoring of the present invention includes a respiratory sensing unit that is worn on a human body and transmits a sensing result for gas breathing with the respiratory system, and is worn on the human body and the Human body information for generating a control signal for controlling the sleeping state of the human body according to a human body motion sensing unit for transmitting the sensing result of the motion and posture of the human body, and the result of the sensing by the respiratory sensing unit or the human body motion sensing unit It is characterized in that it comprises a processing unit 300 and a sleep state control unit that executes an operation for controlling the sleep state of the human body according to a control signal from the human body information processing unit 300 .

The sleep disorder response system through real-time monitoring of the present invention as described above exhibits the following effects.

First, it responds to sleep disorders such as snoring and sleep apnea by inducing the sleeper to change the sleeping posture, and transforms the mattress of the bed to facilitate oxygen supply to the sleeper's respiratory system so that the sleeper can have a good night's sleep.

Second, by wirelessly configuring the respiratory sensing unit or the human body motion sensing unit that measures and transmits the human body information of the sleeping person, it is possible to monitor the human body information and control the sleeping state without restraining the sleeping person.

Third, it is possible to remotely monitor the sleeper's human body information in real time or to control the sleeping state.

1 is an exemplary view in which a respiratory sensing unit and a human body motion sensing unit are worn on a human body in an embodiment according to the present invention;
Figure 2 is an exemplary view applying the sleep disorder response system in the embodiment according to the present invention to the bed.
3 is an overall configuration diagram of a sleep disorder response system through real-time monitoring in an embodiment according to the present invention.

Hereinafter, preferred embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

1 shows an example in which a respiratory sensing unit and a human body motion sensing unit are worn on a human body in an embodiment according to the present invention.

First, the respirator sensing unit 100 is configured to be worn at the inlet of the respirator, including an air amount sensor 111 , a CO2 sensor 112 , a sensor signal conversion module 120 , and a sensing data transmission module 130 . . The respiratory sensor 100 is provided in a position where the air amount sensor 111 and the CO2 sensor 112 can be worn on the nose or mouth, and is formed in a shape that can be worn on the head of the human body. It includes a sensor signal conversion module 120 for converting the analog signal generated by the digital data into digital data and a sensing data transmission module 130 for transmitting the converted digital data.

The air amount sensor 111 of the respiratory sensing unit 100 measures the amount of air that is inhaled or exhausted from the respiratory inlet of the human body to which the respiratory sensing unit 100 is worn, and the CO2 sensor 112 is the above-described It measures the amount of CO2 contained in the air that is inhaled or exhausted, and is provided to check the breathing state of the sleeper. In particular, since it is worn on the face of the human body, it is preferable to form it in a small, light, and ergonomic shape so that sleep is not disturbed even when worn on the face, and the wear is not released during sleep.

In addition, the sensing data transmission module 130 of the respiratory sensing unit 100 preferably transmits the sensed human body information wirelessly, and short-range wireless communication such as Zigbee or wireless LAN may be used. In order to use such wireless communication, the sensor signal conversion module 120 of the respiratory sensing unit 100 converts an analog signal measured by a sensor in the respiratory sensing unit 100 into digital data for wireless transmission. In addition, the data transmission from the respiratory sensing unit 100 is not limited to the case of wireless transmission, and in order to secure power supply and transmission stability, the analog signal measured by the sensor in the respiratory sensing unit 100 is operated by the human body. It may be transmitted by being connected to the sensing unit 200 by wire.

The human body motion sensing unit 200 includes an electrocardiogram (ECG) sensor 211, an acceleration sensor 212, a gravity sensor, a sensor signal conversion module, and a sensing data transmission module 230 to be worn on a part of the human body. it is configured to The ECG sensor 211 included in the human body motion sensing unit 200 measures an electrocardiogram of a human body in which the human body motion sensing unit 200 is worn. It is placed on the inner surface of the band to be worn on the body, or a terminal provided separately is connected to the human body motion sensing unit 200 so that it can be used.

The acceleration sensor 212 measures the movement of the human body, such as movement according to the breathing of the chest or abdomen of the human body. It can be connected to a band and configured to measure a change in movement or elasticity. In addition, the gravity sensor is for measuring the posture of the human body, is worn on a part of the human body, and can check the posture of the human body by measuring the inclination of the human body. This gravity sensor is preferably worn on the chest of the human body to check the posture, and this gravity sensor is additionally provided to wear it on other parts of the human body and connected by wire or wirelessly to provide a plurality of gravity sensors to measure the posture of the human body. You may want to measure it in more detail.

In addition, it is preferable that the sensing data transmission module 230 of the human body motion sensing unit 200 transmits the sensed human body information wirelessly like the sensing data transmission module 130 of the respiratory sensing unit 100, and Zigbee ), short-range wireless communication such as wireless LAN may be used. In order to use such wireless communication, the sensor signal conversion module 220 of the human body motion sensing unit 200 converts an analog signal measured by a sensor connected to the human body motion sensing unit 200 into digital data for wireless transmission.

When the above-described respiratory sensing unit 100 transmits an analog sensor signal by wire, the analog sensor signal received from the respiratory sensing unit 100 is also converted and transmitted. In addition, the sensor signal conversion module 220 and the sensing data transmission module 230 may be separately configured to be worn on a part of the human body or provided at a position close to the human body.

Figure 2 is a view showing that the sleep disorder response system is mounted on the bed according to an embodiment of the present invention. Although the figure shows the mattress (701, 702, 703) of the bed by dividing it into three parts, this is to explain examples of various configurations for transforming the mattresses (701, 702, 703), and the mattress divided into three parts ( 701, 702, 703).

The bed of FIG. 2 is configured to include a human body information processing unit 300 , a sleep state control unit 400 , a human body information display unit 500 , mattresses 701 , 702 , 703 , and supports 710 , 720 , 730 . First, the human body information processing unit 300 receives the human body information sensed from the respiratory sensing unit 100 or the human body motion sensing unit 200 described with reference to FIG. 1 to determine the sleeping state of the human body and control for controlling the sleeping state. generate a signal

The sleep state control unit 400 controls the motor for deforming the mattresses 701 , 702 , and 703 according to the control signal from the human body information processing unit 300 . By the control of this motor, the supports 710, 720, 730 of the mattresses 701, 702, and 703 move, and accordingly, the mattresses 701, 702, and 703 are deformed to change the posture of the human body to control the sleeping state. will be. In FIG. 2 , the sleep state control unit 400 is illustrated separately from the motors 451 , 452 , and 453 for convenience, but it should be noted that the motor is also included in the sleep state control unit 400 .

Deformation of the mattresses 701 , 702 , and 703 to change the posture of the sleeping person to control the sleeping state may be realized by various configurations as follows.

First, by connecting the motor 1 (451) to the support 710 supporting the mattress 1 (701), the height or inclination of the mattress 1 (701) can be changed. To this end, by dividing the support 710 for supporting the mattress 1 701 into a plurality of zones, it is possible to change the posture by dividing the parts of the human body.

In addition, by placing the support 720 in the mattress 2 (702) and connecting the support 720 divided into several joints to move by the motor 2 (452), the mattress 2 (702) is folded or It can be deformed to bend. In this case also, by dividing the support 720 positioned inside the mattress 2 702 into a plurality of zones, it is possible to change the posture by dividing the body part by part.

In addition, as in the massager that massages the back of the human body lying down by the movement of the device formed in the mattress, the support 730 and the motor 3 453 are positioned in a plurality of the mattress 3 703, and several motor 3 By moving the 453 at the same time to deform the shape formed by the several supports 730 , the mattress 3 703 may be deformed according to the shape formed by the support 730 . In this case, the support 730 and the motor 3 453 positioned inside the mattress 3 703 are configured in plurality according to the region, so that the posture can be changed according to the parts of the human body.

What has been described through the mattress 1 (701), the mattress 2 (702), and the mattress 3 (703) is to explain various examples of transforming the mattresses (701, 702, 703), and the mattress must be divided into several parts. It should be understood that, if the mattress can be deformed, it may be composed of various mechanisms such as chains, hydraulic presses, etc. other than the supports (710, 720, 730).

3 shows an overall configuration diagram of a sleep disorder response system through real-time monitoring in an embodiment according to the present invention. The human body information display unit 500 displays the sensed human body information or the determined sleep state on the screen so that a guardian or a medical person can check the sleep state of the human body in real time. In addition, the human body information processing unit 300 transmits the above-described human body information or information such as a sleep state to a medical person, an administrator, etc., and receives a control signal from the outside to enable remote management. In addition, the human body information processing unit 300 may control the additional device 600 such as an alarm worn by the guardian according to the above-described human body information. The human body information processing unit 300, the sleep state control unit 400 and the human body information display unit

The operation of 500 will be described in detail later.

The respiratory sensing unit 100 or the human body motion sensing unit 200 transmits the human body information sensed by being worn on the human body to the sensing data receiving module 310 of the human body information processing unit 300 . As described with reference to FIG. 1 , the sensor signal conversion module 120 and the sensing data transmission module 130 included in the respiratory sensing unit 100 include the respiratory sensing unit 100 and the human body motion sensing unit 200 by wire. When connected, the human body information may be transmitted using the sensor signal conversion module 220 and the sensing data transmission module 230 provided in the human body motion sensing unit 200 .

The human body information processing unit 300 includes a sensing data receiving module 310 , a sleep state determination module 320 , a control signal generating module 340 , a control signal transmitting module 350 , an alarm signal generating module 370 , and additional device communication. It is configured to include a module 380 , and a remote management communication module 390 . The sensing data receiving module 310 receives human body information sensed from the respiratory sensing unit 100 or the human body motion sensing unit 200 . The sensed human body information is preferably received wirelessly, and short-range wireless communication such as Zigbee or wireless LAN may be used.

The sleep state determination module 320 determines the sleep state of the human body using the human body information received by the sensing data receiving module 310 . It is determined whether a sleep disorder such as snoring or sleep apnea has occurred using information such as respiration volume, CO2 concentration, respiratory cycle, heart rate, and sleeping posture included in the human body information. This can be used to determine the sleep state of the human body by accumulating the human body information during sleep of people with sleep disorders such as snoring and sleep apnea, and the sleep state based on a certain number by combining individual information included in the human body information can also be identified.

The control signal generation module 340 generates a control signal for controlling the sleep state according to the sleep state determined by the sleep state determination module 320 . In an embodiment according to the present invention, the sleeping state is controlled by changing the sleeping posture using the deformation of the mattress (701, 702, 703) of the bed, and controlling the motor so that the mattress (701, 702, 703) is deformed. to generate a control signal for For example, the central part of the bed rises up and convexly deforms to induce the sleeper to change his or her posture, or to secure the breathing passage of the human body by convexly deforming a part of the mattress corresponding to the sleeper's neck. control will be possible. Control signals for these various types of control may be provided in advance, and different control signals may be transmitted according to the sleeping state of the human body.

Control signal transfer module 350 transmits the sleep state control signal from the control signal generation module 340 to the sleep state control unit (400). In the embodiment according to the present invention, since the human body information processing unit 300 and the sleep state control unit 400 are included in the bed, the control signal may be transmitted by wire, and in this case, the control signal transmission module 350 and the sleep state Even if the control signal receiving module 410 of the control unit 400 is not separately provided, the sleep state control unit 400 may be controlled.

The alarm signal generation module 370 generates an alarm signal to notify the sleeper or guardian when the sleep state of the human body determined by the sleep state determination module 320 requires an action by the sleeper himself or a guardian, and this The generated alarm signal is transmitted or the additional device 600 is operated accordingly.

The additional device communication module 380 operates the additional device 600 by receiving the alert signal from the alert signal generating module 370 . For example, when sleep apnea occurs in a sleeper, if the guardian is wearing an electronic bracelet equipped with a speaker, display, vibrator, etc. is determined to be sleep apnea, an alarm signal is generated from the alarm signal generating module 370, and the additional device communication module 380 that has received the alarm signal includes a speaker, display, An alarm signal is transmitted to the electronic bracelet so that the vibrator and the like are operated.

For the above-described transmission, an interface may be configured in the same type of transmission method as the sensing data receiving module 310 for receiving human body information to be compatible with the transmission of sensed human body information, or a common network interface may be used. . In addition, in addition to the electronic bracelet, it can be placed close to the human body to directly transmit an alarm signal to the sleeping person as sound, light, vibration, etc., and can be used by connecting various additional devices 600 that operate according to human body information It is of course possible to

The remote management communication module 390 is connected to the remote management system 900 through a communication network, and both wired and wireless connections are possible. In particular, information on the human body information received from the human body information processing unit 300 , the determined sleep state, and the generated control signal or alarm signal is transmitted to the remote management system 900 connected through the communication network, and the remote management system 900 . It may receive a control signal from the sleep state control unit 400 may be transmitted. This makes it possible to monitor the state of the human body even from a remote location, so that it can be handled quickly even in an emergency, and has the effect of executing measures to control the sleep state without visiting in person.

On the other hand, the control signal receiving module 410 of the sleep state control unit 400 that has received the control signal from the control signal transmitting module 350 of the human body information processing unit 300 transmits the control signal to the motor control module 430 to transmit the control signal to the motor. Allow 450 to operate. The motor control module 430 controls to drive a motor equipped to fit a motor that performs various operations according to the received control signal. Accordingly, in the embodiment of the present invention, by operating the various motors 451 , 452 , 453 described with reference to FIG. 2 , the mattresses 701 , 702 , 703 are deformed, and the sleeping state is changed by allowing the sleeper to change the posture accordingly. will be able to control it.

On the other hand, the human body information display unit 500 displays information on the human body information received from the human body information processing unit 300, the determined sleep state, the generated control signal or alarm signal, etc. through a monitor, etc., and displays the state of the human body. It allows you to check in real time. In addition, the status of each module included in the human body information processing unit 300 may be displayed, and settings for operation of each module may be executed.

As described above, the sleep disorder response system through real-time monitoring for controlling the sleep state by modifying the mattresses 701, 702, and 703 in the embodiment according to the present invention has been described, but it is not limited to the mattress of the bed, and the sleep of the human body It should be understood that the sleep state control unit 400 may be configured by connecting devices such as an air purifier, humidifier, and electric heater for controlling the state, as well as devices such as a medical injection injector and a defibrillator.

In addition, the configurations shown in the embodiments and drawings described in the present specification are only the most preferred embodiment of the present invention and do not represent all of the technical spirit of the present invention, so at the time of the present application, various It should be understood that there may be equivalents and variations.

100: respiratory sensing unit 111: air amount sensor
112: CO2 sensor 120, 220: sensor signal conversion module
130, 230: sensing data transmission module 200: human body motion sensing unit
211: ECG sensor 212: acceleration sensor
213: gravity sensor 300: human body information processing unit
310: sensing data receiving module 320: sleep state determination module
340: control signal generation module 350: control signal transmission module
370: alarm signal generating module 380: additional device communication module
390: remote management communication module 400: sleep state control unit
410: control signal receiving module 430: motor control module
450, 451, 452, 453: Motor 500: Human body information display unit
600: attachment devices 701, 702, 703: mattress
710, 720, 730: support 900: remote management system

Claims (13)

Respiratory sensing unit that is worn on the human body's respirator and transmits the sensing result of the gas to be breathed by the respirator; a human body motion sensing unit which is worn on the human body and transmits a sensing result of the movement and posture of the human body; a human body information processing unit for generating a control signal for controlling the sleeping state of the human body according to a result sensed by the respiratory sensing unit or the human body motion sensing unit; a sleep state control unit that executes an operation for controlling the sleep state of the human body according to a control signal from the human body information processing unit; Sleep disorder response system through real-time monitoring, characterized in that it comprises a. The method according to claim 1, wherein the respirator sensing unit, an air amount sensor worn at the inlet of the respirator to measure the amount of gas to be breathed into the respirator; a CO2 sensor for measuring the amount of carbon dioxide contained in the gas exhaled by the respirator; A sleep disorder response system through real-time monitoring, characterized in that it wirelessly transmits the sensed result, including a. The method according to claim 1, wherein the human body motion sensing unit comprises: an ECG sensor for measuring an electrocardiogram of the human body; an acceleration sensor for measuring the movement of the human body; a gravity sensor for measuring the posture of the human body; Sleep disorder response system through real-time monitoring, characterized in that it comprises a. The system for responding to sleep disorders through real-time monitoring according to claim 3, wherein the result sensed by the human body motion sensing unit is transmitted wirelessly. The method according to claim 2 or 4, wherein the respiratory sensing unit or the human body motion sensing unit, the sensor signal conversion module for converting the analog signal from the sensor shown as a result of the sensing into digital data for wireless transmission; a sensing data transmission module for wirelessly transmitting the digital data converted by the sensor signal conversion module; Sleep disorder response system through real-time monitoring, characterized in that it comprises a. The method according to claim 1, wherein the human body information processing unit, the respiratory sensing unit or the human body motion sensing unit sensing data receiving module for receiving the sensing result; a sleep state determination module for determining a sleep state of the human body using a result received by the sensing data receiving module; a control signal generating module for generating a control signal for controlling the sleep state of the human body according to the sleep state determined by the sleep state determination module; Sleep disorder response system through real-time monitoring, characterized in that it comprises a control signal transmission module for transmitting the control signal generated by the control signal generation module. The method according to claim 1, wherein the sleep state control unit comprises: a control signal receiving module for receiving a control signal from the human body information processing unit; a motor for moving the support for supporting the mattress of the bed; a motor control module for operating the motor according to the control signal received by the control signal receiving module; Sleep disorder response system through real-time monitoring, characterized in that it comprises a. The method according to claim 7, wherein the support for supporting the mattress divides the mattress into a plurality of zones so that the mattress corresponding to the divided zone can be deformed according to the operation of the motor to move the support. Sleep disorder response system through real-time monitoring. The method according to claim 7, wherein the support for supporting the mattress is located inside the mattress, the support is divided into a plurality of sections, and the support is divided by the operation of the motor to distinguish and move the support corresponding to each of the divided sections. Sleep disorder response system through real-time monitoring, characterized in that the mattress surrounding the support can be deformed according to the form to be formed. The method according to claim 6, wherein the human body information processing unit comprises: an alarm signal generating module for generating an alarm signal according to the sleep state determined by the sleep state determination module; an additional device communication module for transmitting an alarm signal generated by the alarm signal generating module to an additional device; Sleep disorder response system through real-time monitoring, characterized in that it further comprises. The system for responding to sleep disorders through real-time monitoring according to claim 10, wherein the additional device receives the alarm signal and drives a speaker means, a display means, or a vibration means. The method according to claim 6, wherein the human body information processing unit transmits the result of sensing by the respiratory sensing unit or the human body motion sensing unit or the sleep state determined by the sleep state determination module, and transmits a control signal for controlling the sleep state of the human body. a remote management communication module for receiving; Sleep disorder response system through real-time monitoring, characterized in that it further comprises. The apparatus according to claim 1, further comprising: a human body information display unit for displaying a result of sensing by the respiratory sensor or the human body motion sensing unit and a sleep state of the human body; Sleep disorder response system through real-time monitoring, characterized in that it further comprises.

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