KR101021155B1 - Apparatus for preventing Sudden Infant Death and Infant Monitoring System by Using The Same - Google Patents

Abstract

The present invention relates to an infant sudden death prevention device and an infant monitoring system using the same, and collects infant state information indicating infant's blood oxygen saturation, infant's posture, ambient temperature, noise, and the like, and analyzes the infant's current state by using the same. In addition, alarm sounds according to the analysis result to take necessary action. According to the present invention, even when a parent of an infant cannot directly observe the infant, the child may check in real time whether or not the risk due to the difficulty of breathing of the infant may be immediately taken.

Sudden Infant Death Syndrome, Oxygen Saturation, Acceleration, Temperature, Noise, Alarm

Description

Apparatus for preventing Sudden Infant Death and Infant Monitoring System by Using The Same}

The present invention relates to an infant sudden death prevention device and an infant monitoring system using the same. More particularly, the blood oxygen saturation and infant condition information of the infant are collected, the current state of the infant is analyzed using the same, and an alarm is determined according to the analysis result. The present invention relates to an infant sudden prevention device for generating sound and an infant monitoring system using the same.

Sudden Infant Death Syndrome (SIDS) is a sudden instantaneous birth of a newborn or infant (within 12 months of age) whose mortality cannot be found by post-mortem examinations, such as autopsy or post-mortem conditions or medical history.

About 10 infants die every week in the United Kingdom and about 6,000 infants die each year in the United States, most of whom die from breathing while they are asleep, but the cause is not clear.

Sudden deaths in children are almost under one year old, of which less than six months account for 80%. In particular, the frequency of occurrence is known to be high in infants 2 to 3 months of age.

Infants less than 12 months old can sleep most of the time because they cannot control their bodies. At this time, the infant may suffocate in the process of inverting or inverting the body.

Therefore, in the case of infants within 12 months of age, it is necessary to be always monitored by parents or guardians. However, since it is impossible for the guardian to observe the infant for 24 hours, a device is required to monitor the condition of the infant and indicate whether it is dangerous even when the guardian is difficult to observe the infant.

In particular, there is a need for a device that can prevent sudden death of the infant by monitoring the infant is lying down, whether you are breathing properly, whether the ambient temperature is appropriate, etc. from time to time.

It is an object of the present invention to provide an infant abrupt prevention device and an infant monitoring system using the same to notify the state of the infant by observing the infant in real time instead of the parent or guardian.

It is another object of the present invention to provide an infant sudden prevention device and an infant monitoring system using the same to generate an alarm sound and take immediate action when the infant is in a dangerous state.

Other objects and advantages of the present invention can be understood by the following description, and more clearly understood by the embodiments of the present invention. In addition, the objects and advantages of the present invention can be realized by the means shown in the claims and combinations thereof.

One preferred embodiment of the infant sudden death prevention apparatus of the present invention for solving the above problems, the oxygen saturation sensor for measuring the blood oxygen saturation of the infant, the controller for generating an alarm signal according to the measured oxygen saturation, and the alarm And an alarm unit for generating an alarm sound according to the signal, wherein the controller generates an alarm signal when the measured oxygen saturation is lower than a preset reference value.

Another preferred embodiment of the infant sudden death prevention apparatus of the present invention, the oxygen saturation sensor module for measuring the blood oxygen saturation of the infant and transmits it to the outside, and the blood oxygen saturation of the infant, the received blood oxygen saturation and infant And analyzing the infant state information collected by detecting the state of the child, and the infant state detection module for generating an alarm sound according to the analysis result.

Here, the oxygen saturation sensor module includes an oxygen saturation sensor for measuring blood oxygen saturation of the infant, and first communication means for transmitting the measured blood oxygen saturation to the infant condition detection module.

The infant state detection module may further include second communication means for receiving blood oxygen saturation transmitted by the first communication means, an acceleration sensor for detecting posture of the infant and generating posture state information of the infant, and the infant A temperature sensor that detects ambient temperature of the infant and generates temperature state information of the infant, a sound sensor that detects ambient noise of the infant and generates noise state information of the infant, the oxygen saturation of the blood, and posture state information of the infant It includes a control unit for analyzing the temperature state information of the infant and the noise state information of the infant, and generates an alarm signal according to the analysis result, and an alarm unit for generating an alarm sound in accordance with the alarm signal.

On the other hand, preferred embodiments of the infant monitoring system using the infant sudden death prevention device of the present invention, a plurality of infant sudden death prevention device for detecting and transmitting the blood oxygen saturation and infant state information of each infant, and the plurality of infant sudden death A relay device for receiving blood oxygen saturation and infant state information of each infant from a prevention device, and receiving and displaying blood oxygen saturation and infant state information of each infant from the relay device on a screen and displaying blood oxygen of each infant Including the infant monitoring device for analyzing the saturation and infant condition information, and generates an alarm sound according to the analysis result.

Here, the infant sudden death prevention device, the oxygen saturation sensor module for measuring the blood oxygen saturation of the infant, the infant state detection module for generating the infant state information by detecting the state of the infant, the blood oxygen saturation and infant of the infant It comprises a wireless communication unit for transmitting the status information to the relay device.

In addition, the infant monitoring device, the communication unit for receiving the blood oxygen saturation, infant status information and unique identification code of each infant from the relay device, the blood oxygen saturation and infant status information for each infant using the unique identification code And a display unit for displaying blood oxygen saturation and infant state information for each infant on the screen, and analyzing blood oxygen saturation and infant state information for each infant and generating an alarm signal according to an analysis result. It comprises a main server and an alarm unit for generating an alarm sound in accordance with the alarm signal.

According to an embodiment of the present invention, even when a parent of an infant cannot directly observe the infant, it is possible to check in real time whether or not the risk due to the difficulty of breathing of the infant, etc., can immediately take action accordingly.

In addition, by analyzing blood oxygen saturation and infant condition information, different alarm sounds are generated depending on the severity of the situation, allowing the guardian to immediately check the infant's condition and take prompt action according to the situation. have.

In addition, the infant sudden death prevention device may be implemented in the form of gloves or socks to be worn on the infant's hands or feet, in this case, while protecting the infant's hands or feet, it is possible to observe the state of the infant.

Hereinafter, an embodiment of an infant sudden death prevention apparatus and an infant monitoring system using the same will be described with reference to FIGS. 1 to 6. However, this is only an example and the present invention is not limited thereto.

In describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intention or custom of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

In addition, preferred embodiments of the present invention to be carried out below are provided in each system functional configuration to efficiently describe the technical components constituting the present invention, or system functions that are commonly provided in the technical field to which the present invention belongs. The configuration is omitted as much as possible, and will be described mainly on the functional configuration that should be additionally provided for the present invention. If those skilled in the art to which the present invention pertains, it will be easy to understand the functions of the components that are used in the prior art among the omitted functional configuration not shown below, and also the configuration omitted as described above The relationship between the elements and the components added for the present invention will also be clearly understood.

As a result, the technical spirit of the present invention is determined by the claims, and the following examples are one means for efficiently explaining the technical spirit of the present invention to those skilled in the art to which the present invention pertains. It is only.

1 is a block diagram showing an embodiment of an infant sudden death prevention apparatus of the present invention.

Referring to FIG. 1, the infant sudden death prevention apparatus 100 of the present invention generates an oxygen saturation sensor 110 for measuring oxygen saturation in the blood of an infant, and generates an alarm signal when the measured oxygen saturation indicates a predetermined reference value or less. The control unit 120 and the alarm unit 130 for generating an alarm sound in accordance with the alarm signal of the control unit 120.

In the infant sudden death prevention apparatus 100 configured as described above, the oxygen saturation sensor 110 measures the blood oxygen saturation (SpO ₂ ) of the infant in real time and transmits it to the control unit 120.

If the infant is not lying down and lying down, the breathing may be temporarily stopped. If the oxygen is not supplied to the body, the blood oxygen saturation in the body is abnormally lowered.

At this time, blood oxygen saturation is measured optically. That is, hemoglobin in the blood shows completely different absorption coefficients for the wavelength of light depending on whether it contains oxygen. The amount of light in the red band (660 nm) and the light in the infrared band (890 to 940 nm) Oxygen saturation can be measured by comparing the amount absorbed at.

The blood oxygen saturation can be seen through the graph shown in FIG. 2, where the ratio can be expressed by Equation 1 below.

Here, AC _RED represents the amount of light absorption in the red band (AC component), DC _RED represents the amount of light absorption in the red band (DC component), AC _IR represents the amount of light absorption in the infrared band (AC component), and DC _IR is The light absorption amount (DC component) of the infrared band is shown.

The controller 120 generates an alarm signal when the blood oxygen saturation measured by the oxygen saturation sensor 110 is less than or equal to a predetermined reference value.

In this case, different types of alarm signals may be generated according to the measured blood oxygen saturation value. For example, a warning signal is generated when the measured blood oxygen saturation value is 95% or less, and an emergency alert signal is generated when the measured blood oxygen saturation value is 90% or less.

The alarm unit 130 generates an alarm sound according to the alarm signal of the control unit 120. At this time, the alarm unit 130 may check the type of the alarm signal, and may generate different alarm sounds according to the type of the alarm signal.

For example, when the alarm signal is an emergency alarm signal, the alarm unit 130 may generate an alarm sound that is louder than a caution alarm signal in a shorter period.

As such, when the alarm sound is generated according to the type of the alarm signal, the guardian can immediately check the degree of the infant's condition, so that the user can quickly take action.

On the other hand, the infant sudden death prevention apparatus 100 of the present invention can be implemented in the form of gloves or socks to be worn on the hand or foot of the infant. In this case, while protecting the hands or feet of the infant, it is possible to measure the blood oxygen saturation of the infant in real time without any inconvenience to the infant.

According to an embodiment of the present invention, even when a parent of an infant cannot directly observe the infant, it is possible to check in real time whether or not the risk due to the difficulty of breathing of the infant, etc., can immediately take action accordingly.

Figure 3 is a block diagram showing another embodiment of the infant sudden death prevention apparatus of the present invention.

3, the infant sudden death prevention apparatus 200 of the present invention measures the oxygen saturation in the blood of the infant oxygen saturation sensor module 210 for transmitting to the outside and the oxygen saturation sensor module 210 to transmit And an infant state detection module 220 that receives blood oxygen saturation, and detects the received blood oxygen saturation and the state of the infant and generates an alarm sound according to the collected infant state information.

Here, the oxygen saturation sensor module 210 includes a first communication means 211, an oxygen saturation sensor 212, the power supply unit 213.

The first communication means 211 performs data communication with the infant state detection module 220. For example, the first communication means 211 transmits the blood oxygen saturation of the infant measured by the oxygen saturation sensor 212 to the infant condition detection module 220.

As the first communication unit 211, a wired communication unit or a wireless communication unit may be used. When using the wireless communication unit, Bluetooth, Blue Wide Band (UWB), Home RF, and Zigbee are used. Short-range wireless communication means such as the above can be used.

The oxygen saturation sensor 212 measures the oxygen saturation in the blood of the infant and transmits it to the first communication means 211.

The power supply unit 213 supplies power to the first communication means 211 and the oxygen saturation sensor 212. A battery may be used as the power supply unit 213.

On the other hand, the oxygen saturation sensor module 210 may be manufactured in the form of gloves or socks to be worn on the hand or foot of the infant. In this case, while protecting the infant's hands or feet, it is possible to measure the oxygen saturation of the infant in real time without causing any inconvenience to the infant.

For example, when the oxygen saturation sensor module 210 is manufactured in the form of a glove and worn on an infant's hand, a light emitting diode is detected when a light source is generated by penetrating a finger from a red light emitting diode and an infrared light emitting diode. do.

At this time, if oxygen is not supplied to the body, reduced hemoglobin increases, and thus, light in the red band having a larger absorption coefficient of reduced hemoglobin is attenuated more than light in the infrared band. Here, blood oxygen saturation of the infant is measured using the amount of light in the red band and the amount of light in the infrared band and the ratio thereof.

By using the oxygen saturation sensor 110, not only when the infant is prone to prone to breathing, but also when the infant is lying down normally, it is possible to immediately check whether there is a danger due to difficulty in breathing or the like.

In addition, the infant condition detection module 220 includes a second communication means 221, an acceleration sensor 222, a temperature sensor 223, a sound detection sensor 224, an alarm unit 225, and a controller 226. It is done by

The second communication means 221 performs data communication with the first communication means 211 and specifically receives blood oxygen saturation of the infant transmitted by the first communication means 211.

Like the first communication means 211, the second communication means 221 may use a wired communication means or a wireless communication means, and when using a wireless communication means, Bluetooth (Blue Tooth), UWB (Ultra) Short-range wireless communication means such as Wide Band), Home RF, and Zigbee may be used.

The acceleration sensor 222 detects the infant's current posture and transmits state information on the infant's posture to the controller 226. The acceleration sensor 222 may use a three-axis acceleration sensor or a two-axis acceleration sensor in the X, Y, Z axis direction.

Looking at the case of using a three-axis acceleration sensor as the acceleration sensor 222, first, the X, Y, Z value when the infant is normally lying as a reference value.

In this way, if the infant is lying down as a reference value, the value of the X coordinate changes when the infant moves left and right, the value of the Y coordinate changes when the infant raises the body, and Z when the infant twists the body. The value of the coordinate changes.

The important value here is the value of the Z coordinate, and when the value of the Z coordinate has a value of the opposite sign compared to the reference value, the infant is completely lying down, and thus the infant is in danger.

The temperature sensor 223 detects a temperature around the infant and transmits temperature state information of the infant to the controller 226.

Sudden Infant Death Syndrome (SIDS) is closely related to temperature, and it is known that infant sudden death syndrome is more likely to occur if the baby is covered with a blanket in the winter or the room temperature is high.

Thus, by measuring the temperature around the infant in real time through the temperature sensor 223, to confirm the temperature around the infant, and to maintain the room temperature at an appropriate temperature to prevent infant death syndrome.

The sound sensor 224 detects noise around the infant, such as a crying sound or a crying sound of the infant, and transmits the noise state information of the infant to the controller 226.

The alarm unit 225 generates an alarm sound according to the alarm signal of the control unit 226. The alarm unit 225 may generate different alarm sounds according to the type of the alarm signal.

The controller 226 controls the operation of each component. Specifically, the second communication means 221 controls to receive the blood oxygen saturation of the infant transmitted by the first communication means 211.

The controller 226 generates an alarm signal to the alarm unit 225 when the received blood oxygen saturation of the infant is less than or equal to a preset reference value.

In this case, another type of alarm signal may be generated according to the received blood oxygen saturation value. For example, a warning signal is generated when the measured blood oxygen saturation value is 95% or less, and an emergency alert signal is generated when the measured blood oxygen saturation value is 90% or less.

In addition, the controller 226 generates an alarm signal to the alarm unit 225 according to the infant condition information transmitted from the acceleration sensor 222, the temperature sensor 223, and the sound sensor 224.

That is, as a result of analyzing the posture state information of the infant transmitted by the acceleration sensor 222, the controller 226 generates an alarm signal to the alarm unit 225 when the infant state is prone. In this case, since the risk of sudden death of the infant is great, the controller 226 generates an emergency alert signal.

As a result of analyzing temperature state information of the infant transmitted by the temperature sensor 223, the controller 226 generates an alarm signal to the alarm unit 225 when the preset reference temperature value is exceeded.

In this case, the controller 226 may generate an attention alert signal or an emergency alert signal according to a degree in which the temperature around the infant exceeds a preset reference temperature value.

For example, when the reference temperature value is set to 20 ° C, if the temperature around the infant is 21 ~ 22 ℃ generates a caution alarm signal, if the temperature around the infant is 23 ~ 25 ℃ generates an emergency alert signal.

In this case, the alarm unit 225 may generate a different type of alarm sound according to the type of alarm signal. When the alarm signal is an emergency alarm signal, a larger alarm sound may be generated in a shorter period than the caution alarm signal. .

As a result of analyzing the noise state information of the infant transmitted by the sound sensor 224, the controller 226 generates an alarm signal to the alarm unit 225 when the noise level exceeds a preset reference value. In this case, the controller 226 may generate a warning signal.

The controller 226 may control the operation of the sound sensor 224 according to a time zone. For example, the controller 226 may control the sound sensor 224 not to operate during a daytime when noise is frequently generated. Can be.

On the other hand, the infant condition detection module 220 is worn on the top of the infant's top or diaper.

According to an embodiment of the present invention, not only when the infant is lying down by using the oxygen saturation sensor module 210 and not breathing properly, even if the infant is lying down normally, whether or not a risk due to shortness of breath is immediately caused. You can check and take action.

In addition, the infant state detection module 200 may collect infant state information such as the posture of the infant, the ambient temperature of the infant, the noise of the infant, and generate an alarm sound accordingly to allow the infant's guardian to take appropriate measures. .

In addition, by analyzing the blood oxygen saturation and infant condition information to generate different alarm sounds according to the severity of the situation, the guardian can immediately check the state of the infant, and take prompt action accordingly.

4 is a view showing the configuration of the infant monitoring system using the infant sudden death prevention apparatus of the present invention. The infant monitoring system of the present invention can be used in a hospital or a postpartum care center newborn baby room, and the present embodiment has been described as an example of a newborn baby room.

Referring to FIG. 4, the infant monitoring system 300 of the present invention includes a plurality of infant sudden death prevention apparatus 310, a relay apparatus 320, and an infant monitoring apparatus 330.

The plurality of infant sudden death prevention device 310 is mounted in the incubator of the newborn room, respectively. The infant abrupt death prevention apparatus 310 detects blood oxygen saturation and infant condition information of the infant, and transmits the same to the relay device 320.

In this case, the infant sudden death prevention device 310 may transmit the blood oxygen saturation and the infant state information of the infant every predetermined time or in real time.

Each of the plurality of infant sudden death prevention apparatuses 310 is provided with a unique identification code, and transmits its own unique identification code when the infant's blood oxygen saturation and infant condition information is transmitted to the relay device 320.

Here, the infant state information includes information about the posture of the infant, information about the ambient temperature of the infant, information about the sound generated by the infant, and the like.

The relay device 320 receives the blood oxygen saturation and infant condition information of the infant from the plurality of infant sudden death prevention apparatuses 310 and transmits the information to the infant monitoring apparatus 330.

The infant monitoring device 330 receives the infant's blood oxygen saturation and infant state information from the relay device 320, and displays the infant state for each infant on a screen so that the nurse can check it at any time.

The infant monitoring device 330 analyzes the blood oxygen saturation and infant condition information of the infant and generates an alarm sound according to the analysis result to notify the nurse of an emergency situation and take action.

In this case, the infant monitoring device 330 sends a text or an e-mail to the parents or guardians of the infant through SMS (Short Message Service) to the infant's status and the actions taken by the nurse.

The infant monitoring device 330 displays the infant status of each infant on a web page, so that parents or guardians of the infants can access the Internet in real time to check the infant's status.

According to an embodiment of the present invention, information on the state of each infant in the incubator can be checked at the same time in real time, and when the infant is in a dangerous situation, an alarm sound is generated so that the nurse can quickly take action.

In addition, parents or guardians of the infants can check the condition of the infants at a remote location from time to time, so they can relax and see other things to see.

5 is a view showing the configuration of the infant sudden death prevention apparatus used in the infant monitoring system of the present invention.

5, the infant sudden death prevention apparatus 310 of the present invention includes an oxygen saturation sensor module 311, an infant condition detection module 312, and a wireless communication unit 313.

The oxygen saturation sensor module 311 measures the oxygen saturation in the blood of the infant and transmits it to the wireless communication unit 313. The oxygen saturation sensor module 311 may be implemented in the form of gloves or socks to be worn on the hand or foot of the infant.

The infant state detection module 312 detects a state of the infant and transmits the infant state information to the wireless communication unit 313. The infant condition detection module 312 is mounted on the infant's top or the front of the diaper.

Here, the oxygen saturation sensor module 311 and the infant state detection module 312 is provided with a communication means, and transmits the blood oxygen saturation and infant state information of the infant to the wireless communication unit 313, respectively.

The infant state detection module 312 includes various sensors such as an acceleration sensor 312-1, a temperature sensor 312-2, a sound sensor 312-3, and the like, and detect the state of the infant through the sensors. Do it.

That is, the acceleration sensor 312-1 provides information on the current posture of the infant, the temperature sensor 312-2 provides information on the ambient temperature of the infant, and the sound sensor 312-3. ) Detects a child's sound and provides information about the child's sound.

The wireless communication unit 313 receives the blood oxygen saturation and the infant state information of the infant and transmits it to the relay device 320, and transmits the unique identification number of the infant sudden death prevention device 310.

The wireless communication unit 313 may use short-range wireless communication means such as Bluetooth, Ultra Wide Band (UWB), Home RF, and Zigbee.

6 is a view showing the configuration of the infant monitoring device used in the infant monitoring system of the present invention.

Referring to FIG. 6, the infant monitoring device 330 of the present invention includes a communication unit 331, a database 332, an alarm unit 333, a display unit 334, a web server 335, an SMS server 336, and an e-mail. Server 337, main server 338.

The communication unit 331 performs data communication with the relay device 320, and specifically, receives the infant's blood oxygen saturation, infant condition information, a unique identification number, and the like from the relay device 320.

The database 332 stores blood oxygen saturation and infant state information of each infant. At this time, the blood oxygen saturation and infant state information for each infant is stored through the unique identification number.

The alarm unit 333 generates an alarm sound under the control of the main server 338. That is, the alarm unit 333 generates an alarm sound according to the alarm signal of the main server 338. In this case, different alarm sounds may be generated according to the type of the alarm signal.

The display unit 334 displays the infant's blood oxygen saturation and infant state information on the screen for each infant.

That is, the display unit 334 displays the infant's blood oxygen saturation, the infant's current posture, the ambient temperature of the infant, the noise level of the infant, and the like, so that the nurses can check the infant.

In this case, under the control of the main server 338, the display unit 334 may reflect this in the display column of the infant when the state of the infant is dangerous or belongs to an emergency situation. For example, the display column of the infant may be displayed in red, or the display column of the infant may be displayed to blink.

The web server 335 displays the infant's blood oxygen saturation and infant state information on a web page for each infant. At this time, the parent or guardian of each infant may check the state of the infant by accessing the web server 335 through an authentication procedure.

In this case, each infant's parent or guardian can easily check the infant's condition from a remote location through the Internet at any time, so that other things can be seen with ease.

According to the control of the main server 338, the SMS server 336 controls the state of the infant and the actions taken by the nurse when the nurse takes action because the infant's state is dangerous or belongs to an emergency situation. Write to SMS to send.

Under the control of the main server 338, the e-mail server 337 controls the infant's condition and the actions taken by the nurses if the infant's condition is dangerous or belongs to an emergency. Send it by e-mail.

The main server 338 controls the operation of each component. In detail, the main server 338 controls the communication unit 331 to receive the blood oxygen saturation level, the infant state information, and the unique identification number of the infant from the relay device 320.

The main server 338 controls the database 332 to store blood oxygen saturation and infant state information of the infant for each infant by using the unique identification number.

In addition, the main server 338 analyzes the received blood oxygen saturation and infant condition information of the infant, and generates an alarm signal to the alarm unit 333 according to the analysis result.

That is, the main server 338 generates a warning signal when the blood oxygen saturation value of the infant is 95% or less, and generates an emergency alert signal when the blood oxygen saturation value of the infant is 90% or less.

The main server 338 analyzes the infant condition information, and as a result, the infant's posture is prone, the infant's ambient temperature exceeds the reference temperature value, or the sound generated by the infant exceeds the reference noise level. The alarm unit 333 generates an alarm signal.

In this case, the main server 338 may be generated by varying the type of alarm signal, such as a caution alarm signal or an emergency alarm signal according to the situation of the infant.

In addition, the main server 338 controls the display unit 334 to display the infant's blood oxygen saturation and infant state information on the screen for each infant.

At this time, when the main server 338 analyzes the blood oxygen saturation and the infant state information, and needs to generate the alarm signal, the main server 338 controls the display unit 334 to reflect this on the display column of the infant.

In addition, the main server 338 controls the web server 335 to display the infant's blood oxygen saturation and infant state information on a web page for each infant.

In addition, the main server 338 analyzes the blood oxygen saturation and infant condition information, and when the infant's condition is dangerous or the nurse takes action due to an emergency situation, the main server 338 corresponds to the infant's condition and the actions taken by the nurses. The SMS server 336 and the e-mail server 337 are respectively controlled to write to the parent or guardian by SMS or to send by e-mail.

Although the present invention has been described in detail with reference to exemplary embodiments above, those skilled in the art to which the present invention pertains can make various modifications to the above-described embodiments without departing from the scope of the present invention. Will understand.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the claims below and equivalents thereof.

1 is a block diagram showing an embodiment of an infant sudden death prevention apparatus of the present invention.

2 is a graph showing the relationship between blood oxygen saturation and ratio.

Figure 3 is a block diagram showing another embodiment of the infant sudden death prevention apparatus of the present invention.

Figure 4 is a view showing the configuration of the infant monitoring system using the infant sudden death prevention apparatus of the present invention.

Figure 5 is a view showing the configuration of the infant sudden death prevention apparatus used in the infant monitoring system of the present invention.

Figure 6 is a view showing the configuration of the infant monitoring device used in the infant monitoring system of the present invention.

Explanation of symbols on the main parts of the drawings

110: oxygen saturation sensor 120: control unit

130: alarm unit

210: oxygen saturation sensor module 211: first communication means

212: oxygen saturation sensor 213: power supply

220: infant condition detection module 221: second communication means

222: acceleration sensor 223: temperature sensor

224: sound detection sensor 225: alarm unit

226 control unit

310: infant sudden prevention device 311: oxygen saturation sensor module

312: infant condition detection module 312-1: acceleration sensor

312-2: Temperature sensor 312-3: Sound detection sensor

313: wireless communication unit 320: relay device

330: infant monitoring device 331: communication unit

332: database 333: alarm unit

334: display unit 335: web server

336: SMS Server 337: Email Server

338: main server

Claims (18)

delete delete delete delete delete delete delete delete A plurality of infant sudden death prevention apparatuses for detecting blood oxygen saturation and infant state information of each infant and transmitting the detected infant information to the outside; A relay device configured to receive blood oxygen saturation and infant state information of each infant from the plurality of infant sudden death prevention apparatuses; And Infant monitoring device that receives the blood oxygen saturation and infant state information of each infant from the relay device and displays on the screen, analyzes the blood oxygen saturation and infant state information of each infant, and generates an alarm sound according to the analysis result ;; The plurality of infant sudden death prevention device transmits its own identification code to the relay device, The infant monitoring device, A communication unit for receiving blood oxygen saturation, infant state information, and a unique identification code of each infant from the relay device; A database for storing blood oxygen saturation and infant state information for each infant using the unique identification code; A display unit configured to display blood oxygen saturation and infant state information on a screen of each infant; A main server analyzing blood oxygen saturation and infant state information of each infant and generating an alarm signal according to an analysis result; And And an alarm unit for generating an alarm sound according to the alarm signal. delete 10. The method of claim 9, The infant sudden death prevention device, An oxygen saturation sensor module for measuring blood oxygen saturation of the infant; An infant state detection module configured to detect a state of the infant and generate infant state information; And And a wireless communication unit configured to transmit blood oxygen saturation and infant state information of the infant to the relay device. The method of claim 11, The infant state detection module, An acceleration sensor detecting the posture of the infant and generating posture state information of the infant; A temperature sensor configured to detect ambient temperature of the infant and generate temperature state information of the infant; And And a sound detection sensor detecting sound generated by the infant and generating sound state information of the infant. delete 10. The method of claim 9, The main server is generated by changing the type of the alarm signal according to the analysis result, And the alarm unit generates another alarm sound according to the type of the alarm signal. 10. The method of claim 9, The main server controls the display unit to reflect and display the situation of the infant in the display column of the infant placed in a situation in which the alarm signal is to be generated on the screen when the analysis result indicates that the alarm signal should be generated. , Infant monitoring system. 10. The method of claim 9, And a web server for displaying blood oxygen saturation and infant condition information of each infant on a web page. 10. The method of claim 9, As a result of the analysis, when the infant's condition is in an emergency situation and takes emergency measures, an SMS server for creating and transmitting information on the infant's status and emergency measures to a parent or guardian of the infant as a short message service (SMS) ; And As a result of the analysis, when the infant's condition is in an emergency and takes emergency measures, the infant includes an email server for creating and sending information on the infant's status and emergency measures by email to a parent or guardian of the infant. Monitoring system. 10. The method of claim 9, The infant state information, Infant monitoring system comprising any one of the posture state information of the infant indicating the infant's posture, the temperature state information of the infant indicating the ambient temperature of the infant, the sound state information of the infant indicating the sound of the infant.

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