JP3634204B2 - Apnea detector - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an apnea detection device that detects an apnea state of a subject by body movement such as breathing and notifies the apnea state by an alarm or the like.
[0002]
[Background]
In recent years, sudden death syndrome (hereinafter abbreviated as SIDS) is the leading cause of death in newborns in Western countries, and in Japan, SIDS is increasing as lifestyles approach Europe and the United States. Based on this situation, there is a need for an apnea detection device that can easily monitor the breathing of newborns in hospitals and homes for 24 hours and that is not breathing, that is, can know the apnea state. It is increasing. Apnea detection devices are also used for the purpose of detecting respiratory conditions of adults with apnea syndrome, breathing circuit disconnection during artificial respiration, and airway obstruction.
[0003]
By the way, a conventional apnea detection device has a detection unit that captures body movement such as breathing directly in contact with the body (Japanese Patent Laid-Open No. 6-63031) and a device that lays it under a mattress, a futon, or the like. (Japanese Patent Application No. 10-285350). Both of these were not provided with a function for displaying the level of the detection signal from the detection means, or a function for storing and displaying the date and time when the apnea condition was detected.
[0004]
[Problems to be solved by the invention]
However, the apnea detection device that does not have the display function described above has the following problems.
(1) When an apneic state is detected, the date and time must be stored by a person other than the subject rushed by an alarm or the like.
(2) In the case of SIDS in newborns, it is important to sound an alarm when an apnea is detected and notify the outside. However, when an apnea is detected in an adult, the generated apnea is more effective than the alarm. Although it may be important to store the number of states, the apnea detection device has a problem that it cannot be performed. Also, in detecting an apnea state of an adult, issuing an alarm also hinders the subject's sleep.
[0005]
In consideration of such problems, we developed an apnea detection device that has the function of measuring body movements due to breathing and heartbeats with a sensor, storing the measured values, and reading the stored data with a personal computer, etc. However, this is a device that does not know the number of apneas, the date and time, etc. that occurred during detection without a personal computer. Therefore, it is desired to develop an apnea detection device capable of displaying a detection signal level and storing and displaying an apnea state detection date and time.
[0006]
An object of the present invention is to provide an apnea detection device capable of storing and displaying the number of apnea detection times and apnea detection date and time by the device itself.
[0007]
[Means for Solving the Problems]
The present invention intends to achieve the above object by providing each device such as a date / time measuring means, a date / time storage means, and a display means in the apnea detection device.
Specifically, the invention according to claim 1 is a detection unit that detects body movement including respiration of a subject and outputs a detection signal, and a detection value based on the detection signal generated from the detection unit is a predetermined threshold value. If it is determined that the subject is in an apnea state by the breath determination unit, the breath determination unit determines that the subject is in an apneic state. A time setting means for setting an apnea time for the storage means to start storing when the apnea state continues for a predetermined time, and a display means for displaying the date and time stored by the storage means, wherein the display means comprises: Equipped with a level display function configured to be able to display the detection signal level generated from the detection meansThe detection means includes a pressure-sensitive pipe that generates pressure fluctuations in synchronization with body movement including breathing of the subject, a pressure-receiving chamber that is connected to the pressure-sensitive pipe and receives pressure, and a back pressure adjacent to the pressure-receiving chamber. And a pressure sensor circuit section that partitions the pressure receiving chamber and the back pressure chamber and detects pressure fluctuations of the pressure sensitive pipe, and the pressure receiving chamber and the back pressure chamber pass through the atmosphere. Open apertures that are holes are formed respectively.This is an apnea detection device.
[0008]
Here, as the apnea detection device, for example, a pressure-sensitive pipe that deforms due to the subject's breathing and the like is generated inside the detection mat on which the subject is placed, and the volume of the pressure-sensitive pipe is connected to the pressure sensor. There is one in which a detection signal generated from a pressure sensor in accordance with a change is processed by a breath determination unit.
As a detection means in the present invention, for example, there is a means for detecting body movement including respiration of a subject using a pressure sensor, a load sensor or the like. Further, the breath determination unit can be configured as a program developed on a CPU that performs arithmetic processing on a detection signal from the detection unit.
[0009]
In the present invention, the storage means includes, for example, a RAM on the CPU that reads and stores time data from a real-time clock, and the display means includes, for example, an output device for printing on paper such as a printer, a CRT, There are display devices using LCD or the like. When confirming the display in real time, it is preferable to display using a display.
Further, the storage means can be configured to start operation when, for example, the apnea state has continued for a certain time, and this time can be set to an arbitrary time in advance for the CPU, for example. .
Further, as the time setting means, for example, there is a means for writing data in a RAM on the CPU and / or an E2PROM. It is preferable to use both of these because it is not necessary to reset the time after replacing the battery of the apnea detection device.
Furthermore, as the level display function, for example, the waveform of the pressure level measured by the pressure sensor is displayed in real time on the display, or the center of the bar graph configured using a plurality of dots is set to the zero level, and the pressure level It is possible to make the dots blink up and down in synchronization with.
[0010]
According to the present invention, since the apnea detection device is provided with the storage means and the display means, the date and time determined as the apnea state by the breath determination means is stored by the storage means, and the data is displayed by the display means. Will be. Therefore, it is possible to store the date and number of times when the apnea state is detected, and to display them by the apnea detection device itself.
[0012]
Also,According to this invention, the level display function provided in the display means displays the level of the detection signal being detected. Therefore, it can be easily determined whether correct detection is being performed. Also, if you are in the spot during detection, you can grasp the moment of apnea without any alarm output, which is advantageous in terms of safety. As a result, it is possible to solve the problem that existed in the conventional apnea detection device, that is, the problem that there is no means for confirming the detection signal level being detected and it is difficult to determine whether normal detection is being performed. .
[0013]
Claim2The invention described inClaim 1The apnea detection device according to claim 1, wherein the alarm means outputs an alarm signal when the apnea state determined by the breath determination means continues for a predetermined time.The time setting means individually sets an apnea time when the alarm means outputs an alarm and an apnea time when the storage means starts storing.This is an apnea detection device.
[0015]
According to the present invention, the apnea time (time determination value 1) at which an alarm is output and the apnea time (time determination value 2) at which the storage means starts storing can be set to different times. Therefore, it is possible to set so that the output to the alarm buzzer and the storage are performed at the same time, or to be performed separately. That is, for example, even when apnea frequency data is required in adults with apnea syndrome, it is possible to repeatedly store only the date and time without sounding an alarm buzzer and stopping detection, It is possible to easily accumulate and use data useful for the treatment of the subject. Moreover, since there is no output to an alarm buzzer only by storing the date and time, it is possible to avoid disturbing the sleep of the subject.
[0016]
Claim3The invention described in claim 1Or claim 2The apnea detection device according to claim 1, wherein the storage unit is configured to be capable of storing a plurality of dates and times, and the display unit has a data display function capable of displaying the number of stored dates and times. It is a detection device.
In the present invention, as the data display function, for example, a function that displays a number corresponding to the stored number on a display or a function that displays the number of dots corresponding to the stored number can be considered.
[0017]
According to the present invention, the number of times that the subject has entered the apnea state is stored by the storage means, and the number is displayed by the data display function. Therefore, even if a third party other than the subject is away from the subject being detected, the number of times the subject has become apnea can be easily known, and useful information for the subject and doctors can be obtained. Can be provided.
[0018]
Claim4The invention described in claim3The apnea detection device according to claim 1, wherein the data display function includes a data sort function for rearranging the dates and times stored in the storage unit in order.
In the present invention, the data sorting function for arranging the date and time in order includes, for example, a function for displaying data from the latest one, a function for displaying data from the oldest one, a function for sorting by day, a function for sorting by time zone, etc. Conceivable.
[0019]
According to the present invention, the stored data is organized by the data sorting function. Therefore, data can be extracted and used in a more user-friendly form.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 1, the apnea detection device 1 detects an apnea state by measuring a detection mat 10 formed in a substantially flat rectangular parallelepiped shape and a pressure fluctuation generated inside the detection mat 10. The alarm monitor 20 is connected by a connecting pipe 40.
[0021]
The configuration of the detection mat 10 will be described with reference to FIG. 2 showing a vertical sectional view taken along line II-II in FIG. 1 and FIG. 3 being a horizontal sectional view taken along line III-III in FIG.
A pressure-sensitive pipe 13 that generates pressure fluctuations in synchronization with body movement including breathing of the subject is disposed at the upper center in the longitudinal direction of the lower plate 11 formed of hard plastic or the like. That is, spacers 14 are attached to both ends of the lower plate 11 in the longitudinal direction to prevent the pressure-sensitive pipe 13 from being crushed too much. An upper plate 12 is placed on top of the pressure-sensitive pipe 13 and the spacer 14, and all these constituent members are covered with a protective cover 15 made of a soft plastic to constitute a detection mat 10.
[0022]
Here, the pressure-sensitive pipe 13 is formed by cutting a tube formed of an elastically deformable material, for example, a silicone resin tube into a predetermined length, one end of which is sealed with a sealing plug 131, and the other end. It is connected to a connection tab 132 that also serves as a noise reduction diaphragm for adjusting the amount of pressure fluctuation due to factors other than body movement. The upper plate 12 is formed of a member that can be elastically deformed by the breathing of the subject, for example, a foam made of vinyl chloride.
When detecting, a mattress or the like may be appropriately mounted on the detection mat 10 and used.
[0023]
As shown in FIG. 4 and FIG. 5, the monitor 20 includes a pressure sensor 21 that captures pressure fluctuations in the pressure-sensitive pipe 13, and an electric circuit 30 that processes an electric signal from the pressure sensor 21. Alarm buzzer 24 and LED 36 for informing the breathing state to the outside, LCD 22 constituting display means together with a display control unit described later, battery 23 for supplying power to them, power key 33 for turning on / off the power, mode switching A mode key 39 for performing various settings, a setting 1 key 38 for performing various settings, and a setting 2 key 37 are provided.
[0024]
The configuration of the pressure sensor 21 will be described in detail with reference to FIG. 6. The pressure sensor 21 is connected to the connecting pipe 40 and has a pressure introduction port formed with a small internal volume so as not to reduce detection sensitivity. 213, a pressure receiving chamber 211 that receives pressure from the inside of the connection pipe 40, and a back pressure chamber 212 adjacent to the pressure receiving chamber 211 via a pressure sensor circuit unit 216 above the pressure receiving chamber 211.
The pressure sensor circuit unit 216 divides the pressure receiving chamber 211 and the back pressure chamber 212 and is disposed in the center of the base 216A having an electronic circuit (not shown) and the base 216A, and detects pressure fluctuations in the pressure sensitive pipe 13. And a pressure sensor chip 216B.
[0025]
The pressure sensor chip 216B includes, for example, a diaphragm that deforms in response to pressure fluctuations. The deformation of the diaphragm is taken out as a distortion amount, capacitance, etc., and converted into an electric signal by an electronic circuit so that pressure can be measured. Yes. In addition, the pressure receiving chamber 211 is formed with a pressure receiving chamber atmosphere opening restriction 215 that is a through hole communicating with the atmosphere. The pressure receiving chamber atmosphere opening restriction 215 has a role of preventing the pressure receiving chamber 211 from being sealed. That is, the internal pressure of the pressure receiving chamber 211 is gradually increased due to expansion or compression of the air in the pressure receiving chamber 211 due to an external factor having a slow pressure response compared to breathing, such as changes in atmospheric pressure, ambient temperature, or body temperature of the newborn. To prevent the detection of minute pressure fluctuations due to respiration.
[0026]
The back pressure chamber 212 is also provided with a back pressure chamber atmosphere opening throttle 214 which is a through hole having the same shape as the pressure receiving chamber atmosphere opening throttle 215. When the back pressure chamber 212 is opened to atmospheric pressure, the back pressure chamber air opening restriction 214 is, for example, due to atmospheric changes such as opening / closing of the door of the room where the apnea detection device 1 is installed or air conditioning wind. The back pressure chamber 212 is directly affected to prevent detection of respiration as usual, and is formed to prevent this.
[0027]
The apnea detection device 1 configured as described above operates as follows. That is, the upper plate 12 is bent by the movement of the body placed on the detection mat 10 and generated by the breathing of the subject. As a result, the volume of the pressure-sensitive pipe 13 changes, and pressure fluctuations occur accordingly. This pressure fluctuation is captured by a pressure sensor 21 provided in the monitor 20 and connected to the pressure sensitive pipe 13 by a connecting pipe 40. The captured change is processed in the electric circuit 30, and if it is determined that the apnea state has continued for a predetermined time (time determination value 1), a warning is given by the alarm buzzer 24 and the LED 36.
[0028]
Next, the configuration of the electric circuit 30 provided in the monitor 20 will be described with reference to FIG. The electric circuit 30 is mainly composed of a CPU 31, and a power circuit 32 for supplying power to the CPU 31 from the battery 23, a power key 33 for turning on / off the power, and a preset time determination value 1. 2 is read, an A / D converter 35 that converts an analog electric signal from the pressure sensor 21 into a digital electric signal, an LED 36 that outputs an alarm by light emission, and a setting 1 key 38 that performs various settings such as a date. A setting 2 key 37, a mode key 39 for switching modes, and a real-time clock 40 for exchanging signals with a certain time interval from the CPU 31 are provided.
[0029]
The CPU 31 includes a control unit 311 that receives an electrical signal from the pressure sensor 21 and controls each component based on the electrical signal, and receives a signal from the control unit 311 to perform arithmetic processing to perform a respiration level value. , And a breath determination unit 312 for determining the breathing state of the subject.
[0030]
In addition, the CPU 31 includes a timer 317, a RAM 318, a ROM 319, a power operation unit 320, an alarm control unit 321, and a display control unit 316. Here, the timer 317 sends a measurement signal to the A / D converter 35 and the control unit 311 every predetermined time T1 that can be arbitrarily set in advance. The RAM 318 includes a counter that increments every time T1, and also functions as a storage unit that stores data such as date and time and a time setting unit in which each time determination value that is set is written. Further, the ROM 319 registers a level determination value as a reference value for apnea determination and the zero point of the pressure sensor 21, and the power operation means 320 supplies power only during measurement in order to reduce battery power consumption. It has a function to make. The alarm control unit 321 performs ON / OFF control of the alarm buzzer 24 and the LED 36, and the display control unit 316 controls each display unit of the LCD 22, which will be described later.
[0031]
Here, the LCD 22 and the display control unit 316 constitute a display unit 324, and the alarm buzzer 24, the LED 36, and an alarm control unit 321 that controls these components constitute an alarm unit 323. The A / D converter 35 converts the measurement value indicating the pressure detected by the pressure sensor 21 into a digital electric signal as a detection signal at every predetermined time T1 when the measurement timing signal from the timer 317 is received. 311 is sent out. Further, the pressure sensor 21, the A / D converter 35, and the timer 317 constitute a pressure measuring unit 322 as a detecting unit that measures the pressure in the pressure sensitive pipe 13 every predetermined time T1. .
In such pressure measuring means 322, changes in the digital electrical signal sent to the control unit 311 during detection of the subject's respiration are, as shown in FIG. 8, a positive pulse signal in the subject's inspiration and a negative pulse in the expiration. It is detected as a signal, and swings regularly in both directions ± around the zero point of the pressure sensor 21.
[0032]
The LCD 22 will be described with reference to FIG. 9. The digital display A that displays the date and time provided with the data display function and the data sort function, and the alarm output that displays the time determination value 1 set in the E2PROM 34 and the RAM 318. A time display unit B, a storage time display unit C that displays a time determination value 2 that is also set, and a pattern D that combines a level display function and a data display function to display the detection level and the number of detected memories are provided. Configured. In the present embodiment, the alarm output time display unit B includes five dots B1 to B5, the storage time display unit C includes five dots C1 to C5, and the pattern D includes 15 dots D1 to D15. ing.
[0033]
The display contents of the LCD 22 will be described with reference to FIG. 10. When the power is turned on by the power key 33, all the dots on the LCD 22 are all lit for 2 seconds (10A). I can confirm. Next, when there is no storage data of apnea detection date and time in RAM 318, the current year and month are displayed in order of 1 second each, then the current time is displayed (apnea detection mode), and detection is started. (10B).
[0034]
On the other hand, if there is stored data of apnea detection date and time in RAM 318, the latest data among the stored data arranged by the data sort function of the data display function after all the dots shown in 10A are turned on, While blinking for 2 seconds each in the order of date and time, the number of memories is displayed in pattern D (10C). When there is one stored data, only D1 is lit, and when there are two data, D1 and D2 are lit. That is, the number of stored data matches the number of dots of pattern D. In the present embodiment, the pattern D includes 15 dots D1 to D15, and can store a maximum of 15 data. When all the blinking displays of the latest data are completed, the same operation as the above-described 10B is performed, and then the mode is shifted to the apnea detection mode to start detection.
In order to erase the stored data, when the power key 33 is turned on while the mode key 39 is pressed, “CP” is displayed for 1 second before all the dots are displayed, and the stored data is erased during this time ( 10D). Thereafter, all-dot display shown in 10A is performed, and the operation moves to the normal apnea detection mode through the operation of 10B.
[0035]
As shown in FIG. 11, during the detection of an apnea state, the digital display unit A displays the current time as described above, and the alarm output time display unit B and the storage time display unit C will be described later. One dot corresponding to the time determination value 1 and the time determination value 2 preset in the E2PROM 34 and RAM 318 by the method is lit. Further, during the detection, the difference between the pressure generated by the body movement including respiration measured every time T1 by the pressure measuring unit 322 and the measured value and the zero point registered value in the ROM 319 is obtained. Thereby, a respiration level value having a positive / negative sign with the zero point registered value as the center is calculated, and this respiration level value is displayed in a pattern D as a level display function at every time T1. Therefore, only by confirming the pattern D, it can be confirmed whether or not a normal apnea state is detected.
[0036]
In this embodiment, a differential pressure sensor of ± 50 Pa is used as the pressure sensor 21, and at 0 Pa, only the dot D8 is lit, and the dot is set to increase or decrease one by one as the pressure increases or decreases by 0.4 Pa. The pressure level value up to ± 2.8 Pa can be confirmed. 11A shows a display example when +1.2 Pa is detected, and 11B shows a display example when -2.4 Pa is detected.
[0037]
FIG. 12 shows changes in the display content of the digital display section A on the LCD 22 as the setting modes are switched. In the apnea detection mode, the current time is displayed on the digital display A in a normal state (12A). Here, when the mode key 39 is pressed once, the current year is displayed on the digital display section A, and the current time setting mode is entered (12B). When the mode key 39 is pressed once again in this state, three characters “ALA” are displayed on the digital display portion A, and the mode shifts to the time determination value 1 setting mode (12C). When the mode key 39 is further pressed, three characters “rEC” are displayed on the digital display portion A, and the mode shifts to the time determination value 2 setting mode (12D). When the mode key 39 is pressed in this state, the current time is displayed on the digital display unit A, and the mode is shifted to the apnea detection mode to resume detection. In this way, the setting modes can be easily switched by simply pressing the mode key 39.
[0038]
The current time setting method is performed using the setting 1 key 38 and the setting 2 key 37 in the current time setting mode, as shown in FIG. In the initial display of the current time setting mode, the last two digits indicating the year are displayed, and the number indicating the tenth digit of the year is blinking (13A). In this state, each time the setting 2 key 37 is pressed once, the number is incremented by 1 and the range from 0 to 9 is shifted. After selecting the tenth digit indicating the current year from the list, pressing the setting 1 key 38 once will cause the number indicating the first digit to blink (13B). The number indicating the current year from 0 to 9 is selected using the 2 key 37, and the year setting is completed.
[0039]
Next, when the setting 1 key 38 is pressed once, the display shifts to the month and day display and the number indicating the month blinks (13C). Here, each time the setting 2 key 37 is pressed, the number changes in the range of 01 to 12, so the number indicating the current month is selected. When the setting 1 key 38 is pressed once in this state, the number indicating the day blinks (13D), and the number indicating the current day is selected from 01 to 31 using the setting 2 key 37 as in the month. The setting of the date ends. When the setting 1 key 38 is pressed once again, this time, the display shifts to the hour and minute display, and the number indicating the hour flashes (13E). Here, each time the setting 2 key 37 is pressed, the number changes in the range of 01 to 24. Therefore, the number indicating the current time is selected. When the setting 1 key 38 is pressed in this state, the number indicating the minute blinks (13F), and the number indicating the current minute is selected from 00 to 59 using the setting 2 key 37 similarly to the hour.
After all numbers have been set, pressing the setting 1 key 38 once returns to the display for setting the first year (13A).
[0040]
As shown in FIG. 14, the time determination value 1 is set using the setting 1 key 38 in the time determination value 1 setting mode. In the time judgment value 1 setting mode, three characters “ALA” are displayed on the digital display part A of the LED 22, and one dot corresponding to the set time judgment value 1 is lit on the alarm output time display part B. (14A). In this embodiment, the settable time is, for example, five types of 15 seconds, 20 seconds, 25 seconds, 30 seconds, and 35 seconds, 15 seconds are the dots B1, 20 seconds are the dots B2, 25 seconds are the dots B3, 30 seconds corresponds to dot B4 and 35 seconds corresponds to dot B5.
[0041]
As shown in 14A of FIG. 14, if the currently set time is 20 seconds, the dot B2 is lit. At this time, each time the setting 1 key 38 is pressed, the dots to be lit change from B3 to B4 to B5 to B1 to B2 (14B to 14E). When 39 is pressed, the mode is shifted to the time determination value 2 setting mode, and at the same time, the set time determination value 1 is written in both the RAM 318 and the E2PROM 34 which are time setting means.
In the present embodiment, the time determination value 1 is set to 30 seconds, for example (see FIG. 11).
[0042]
The method for setting the time determination value 2 is the same operation as the method for setting the time determination value 1 described above (not shown). In the time determination value 2 setting mode, as shown in FIG. 12, three characters “rEC” are displayed, and one dot corresponding to the set time determination value 2 is lit in the storage time display section C. (12D). In this embodiment, the settable time is, for example, five types of 15 seconds, 20 seconds, 25 seconds, 30 seconds, and 35 seconds, 15 seconds is the dot C1, 20 seconds is the dot C2, 25 seconds is the dot C3, 30 seconds corresponds to dot C4 and 35 seconds corresponds to dot C5. Each time the setting 1 key 38 is pressed, the dot that is lit changes. Therefore, when the mode key 39 is pressed after aligning the lit dot at the time to be set, the mode is set at the same time as the apnea detection mode. The value 2 is written in both the RAM 318 and the E2PROM 34 which are time setting means.
In the present embodiment, the time determination value 2 is set to 20 seconds, for example (see FIG. 11).
[0043]
In each of the setting modes described above, the apnea state is not detected. Therefore, in case of entering the setting mode by accidentally pressing the mode key 39 during the apnea detection mode or forgetting to return to the apnea detection mode after entering each setting mode, etc. In the embodiment, when no key operation is performed for 1 minute during each setting mode, the device automatically returns to the apnea detection mode and resumes the detection. In this way, if you leave the place without returning to the apnea detection mode from the setting mode, the detection will start and return to the apnea detection mode. Does not occur.
[0044]
Next, an apnea detection method performed by the apnea detection device 1 in which the various settings described above are performed will be described with reference to the flowchart of FIG.
(1) When the power key 33 is turned on, the pressure sensor 21 and the A / D converter 35 are turned on (processing S1), and after pressure measurement is performed by the pressure sensor 21 (processing S2), the pressure sensor 21 is turned on. And the power supply of the A / D converter 35 is turned off (processing S3), and processing S4 starts.
(2) After the counter 1 provided in the RAM 318 is incremented (processing S4), the respiration determining means 312 obtains the difference between the zero point registered value in the ROM 319 and the pressure measurement value in (1), and the respiration level value is It is calculated (processing S5), and processing S6 is entered.
[0045]
(3) In process S6, it is determined whether or not the calculated respiratory level value is smaller than the level determination value 1 shown in FIG.
(4) If the respiration level value is greater than the level determination value 1, the respiration determining means 312 determines that the subject is respiring, enters step S7, resets the counter 1 to zero, and returns to step S1. .
(5) On the other hand, if the respiration level value is smaller than the level determination value 1, the respiration determination means 312 determines that the subject may have entered an apnea state, and enters step S8.
(6) In process S8, it is determined whether or not the counter 1 is equal to a time determination value 2 (for example, 20 seconds) that is a time to be stored.
[0046]
(7) If the counter 1 is equal to the time determination value 2, the breath determination unit 312 determines that it is necessary to store the date and time when the apnea condition occurred, enters the process S9, and sets the date and time read from the real-time clock 40. After being stored in the RAM 318, the process S10 is entered.
(8) On the other hand, if the counter 1 is not equal to the time determination value 2, the breath determination unit 312 determines that the apnea state has not been maintained enough to store the date and time, and enters the process S10.
(9) In process S10, it is determined whether or not the counter 1 is equal to a time determination value 1 (for example, 30 seconds) during which an alarm is output.
(10) If the counter 1 is equal to the time determination value 1, the breath determination unit 312 determines that the subject's apnea state has continued until the alarm is issued, enters the process S11, and immediately the alarm control unit 321. An alarm signal is output via the LED 36 and an alarm is issued by the LED 36 and the alarm buzzer 24.
(11) On the other hand, if the counter 1 is not equal to the time determination value 1, the respiration determination means 312 determines that the apnea state is not long enough to output an alarm, and does not issue an alarm. It returns to processing S1.
The above processing is performed every time T1 (for example, 100 milliseconds).
[0047]
In the above, by setting the time determination value 1 longer than the time determination value 2 as in the present embodiment, the state where the respiratory level value is less than the level determination value 1 continues to the time determination value 2. Thereafter, only the date and time is stored, and the alarm output by the alarm means 322 is not performed. Thereafter, if the respiration level value becomes equal to or higher than the level determination value 1 by the time determination value 1, the detection is continued. Thus, if the subject is an adult with apnea syndrome or the like, after turning on the power key 33 and erasing the stored data by the above-described method, the detection is started until the power key 33 is turned off. Data on how many times the apnea state has occurred and when it has occurred can be stored in the RAM 318 as storage means. However, when the subject is a newborn and the apnea detection device 1 is used for the purpose of preventing SIDS, it is desirable to set the time determination value 1 and the time determination value 2 to the same time.
[0048]
Next, for example, a confirmation method when there are three stored data will be described with reference to FIG. When the setting 1 key 38 is kept pressed for 2 seconds in the apnea detection mode, the digital data display unit A having the data display function and the data sort function shifts to the stored data display mode. After entering the stored data display mode, the latest stored data among the stored data organized by the data sort function is displayed for 1 second each in the order of year (16A), month (16B), and time (16C). The previous storage data (16D to 16F) and the previous storage data (16G to 16I) are automatically displayed in the same manner as the latest storage data. After displaying the oldest stored data, the latest stored data is displayed again.
[0049]
As described above, the stored data to be displayed is set to change automatically, but the stored data to be displayed can be forcibly switched by pressing the setting 1 key 38. Further, by pressing the mode key 39 while the stored data is being displayed, the mode is shifted to the apnea detection mode and the detection is started.
Note that FIG. 17 briefly summarizes the relationship between the modes described above and the key operations. That is, the power key 33 makes a transition between the power OFF state (17A) and the apnea detection mode (17B), and the apnea detection mode (17B), the current time setting mode (17C), and the time determination value 1 The mode key 39 is used to switch between the setting mode (17D) and the time determination value 2 setting mode (17E). Further, the transition from the apnea detection mode (17B) to the stored data display mode (17F) is performed by pressing the setting 1 key 38 for 2 seconds. From the stored data display mode (17F) to the apnea detection mode (17B). Transition to is performed by the mode key 39. Further, the stored data is erased by simultaneously pressing the power key 33 and the mode key 39 (17G), and then the mode is shifted to the apnea detection mode (17B).
[0050]
According to this embodiment as described above, the following effects are obtained.
That is, in the present embodiment, the apnea detection device 1 is provided with the RAM 318 as the storage means, and the display means 324 including the display control unit 316 and the LCD 22. Is stored in the RAM 31, and the data is displayed on the display means 324. Therefore, the apnea detection device 1 itself can store and display the date / time and the number of times the apnea state is detected.
[0051]
The pattern D having a level display function provided in the display unit 324 displays the level of the detection signal being detected. Therefore, it can be easily determined whether correct detection is being performed. Also, if you are in the spot during detection, you can grasp the moment of apnea without any alarm output, which is advantageous in terms of safety. As a result, it is possible to solve the problem that existed in the conventional apnea detection device, that is, the problem that there is no means for confirming the detection signal level being detected and it is difficult to determine whether normal detection is being performed. .
[0052]
The time until the alarm is output by the alarm means 323 (time determination value 1) and the time until it is stored in the RAM 31 (time determination value 2) can be set to different times. Accordingly, it is possible to set the output to the alarm buzzer 24 and the like to be performed at the same time or to be performed separately. Therefore, for example, even when apnea frequency data is required by an adult with an apnea syndrome, it is possible to repeatedly store only the date and time without sounding the alarm buzzer 24 and stopping the detection. Therefore, it is possible to easily accumulate and use data useful for treatment of a subject. Moreover, since there is no output to the alarm buzzer 24 only by storing the date and time, it is possible to avoid disturbing the sleep of the subject.
[0053]
The number of times and the date and time when the subject became apnea is stored in the RAM 318, and the number and date and time are displayed by the pattern D and the digital display unit A which are data display functions. Therefore, even if a third party other than the subject is away from the subject being detected, it is possible to easily know the number of times the subject has become apnea, providing useful information to the subject and the doctor. it can. The stored data is organized by the data sort function. Therefore, data can be extracted and used in a more user-friendly form.
[0054]
Since the pressure-sensitive pipe 13 is formed of an elastically deformable pipe-like hollow body, the pressure inside the pressure-sensitive pipe 13 can be changed by minute breathing or body movement of the subject. The respiration can be detected precisely accordingly.
[0055]
Since pressure fluctuations occur in the pressure sensitive pipe 13 as the upper plate 12 is deformed by the movement of the body of the subject, the subject turns over on the upper plate 12 from a position just above the pressure sensitive pipe 13 when turning over. Even if the subject moves to an arbitrary location, unless the subject is removed from the upper plate 12, the pressure sensing pipe 13 fluctuates with the deformation of the upper plate 12, so that the subject's breathing is easily detected. can do.
Further, since the lower plate 11 is formed of a hard member that does not elastically deform, the pressure applied to the pressure-sensitive pipe 13 with the deformation of the upper plate 12 is hardly absorbed by the lower plate 11, and the pressure-sensitive pipe. The sensitivity of the pressure fluctuation inside 13 can be improved, and as a result, the sensitivity of detecting respiration can be improved.
[0056]
Since the pressure-receiving chamber atmosphere opening restriction 215 is formed in the pressure-receiving chamber 211, the internal pressure of the pressure-receiving chamber 211 can be quickly returned to the atmospheric pressure state even if pressure fluctuation occurs temporarily due to an external factor. Only pressure fluctuations associated with respiration can be measured in a very small range.
In addition, since the back pressure chamber atmosphere opening throttle 214 is formed in the back pressure chamber 212, it is possible to alleviate a sudden change in the atmosphere, and to make the pressure receiving chamber 211, the throttle and the volume in the space the same shape. The effect of a sudden change in atmospheric pressure can be reduced.
[0057]
Since the connection tab 132 that also serves as a noise reduction diaphragm is provided, extra components such as vibration due to external factors can be reduced, and the pressure waveform obtained from pressure fluctuations due to breathing can be smoothed and stabilized. A good respiratory waveform can be extracted.
[0058]
It should be noted that the present invention is not limited to the above-described embodiment, and modifications and improvements as long as the object of the present invention can be achieved are included in the present invention. For example, in the above-described embodiment, the apnea detection device 1 that includes the detection mat 10 and the monitor 20 is used. However, the present invention is not limited to this, and for example, a sensor portion may be attached to the body. However, it is preferable to use the apnea detection device 1 having the configuration as in this embodiment because there is no problem that the sensitivity is significantly different depending on the portion to which the pressure measurement unit 322 as the detection unit is attached.
[0059]
In the above embodiment, the LCD 22 is used as one component of the display means. However, the present invention is not limited to this. For example, a device using a device such as a printer or another display device such as a CRT is used. It may be a thing. In the embodiment, the RAM 31 is used as the storage unit. However, the present invention is not limited to this, and for example, the E2PROM 34 may be used. Furthermore, in the above-described embodiment, the alarm unit 323 includes the alarm control unit 321, the LED 36, and the alarm buzzer 24, but is not limited thereto. For example, the direct control unit 311 without providing the alarm control unit 321. It is not always necessary to provide both the LED 36 and the alarm buzzer 24. However, the one provided with the alarm buzzer 24 as in this embodiment is more advantageous when notifying the apnea state to the outside.
[0060]
In the above-described embodiment, the control unit 311 and the breath determination unit 312 are provided separately. However, the present invention is not limited to this. For example, these units may be integrated, and other control units are provided. Also good. In addition, the constituent members such as the timer 317, the power operation unit 320, the ROM 319, and the RAM 318 may be integrated in the control unit 311. Furthermore, in the above-described embodiment, the set time determination values 1 and 2 are read using the E2PROM 34 and the RAM 318. However, the present invention is not limited to this, and the reading may be performed using only the RAM 31, for example. However, it is preferable to use the E2PROM 34 because the data of the time determination values 1 and 2 set even when the battery of the apnea detection device 1 is replaced does not disappear. In the embodiment, the time determination value 1 is set to 30 seconds and the time determination value 2 is set to 20 seconds. However, the present invention is not limited thereto, and may be set as appropriate according to the subject and the detection purpose. For example, when the subject is a newborn and the apnea detection device 1 is used for the purpose of preventing SIDS, it is preferable to set the time determination value 1 and the time determination value 2 to the same value, for example, 20 seconds.
[0061]
In the above-described embodiment, the three keys of the mode key 39, the setting 1 key 38, and the setting 2 key 37 are used as setting keys. However, the present invention is not limited to this, and more keys may be used. The name is not limited to these. In the above embodiment, the pattern D is used as one component of the data display function and the stored number is displayed by the number of dots displayed on the pattern D. However, the present invention is not limited to this. For example, the digital display unit A A number indicating the stored number may be displayed on the screen. Furthermore, although the data sort function in the said embodiment was supposed to be displayed from the latest stored data, it is not limited to this, and for example, it may be displayed in the oldest order.
[0062]
In the above-described embodiment, the pressure measuring unit 322 (the pressure sensor 21 is a main part) is used as the detecting unit. However, the present invention is not limited to this. For example, other detecting units using a load sensor or the like may be used. Good. Further, although the connection pipe 132 that also serves as a noise reduction diaphragm is provided in the pressure-sensitive pipe 13, it is not limited to this. For example, in the case of a sealed structure, when the subject is placed on the detection mat 10, the pressure-sensitive pipe 13 is always compressed, and the pressure measurement value fluctuates to a positive pressure value above a certain level. The presence or absence of the subject on the detection mat 10 may be determined using the conditions.
[0063]
【The invention's effect】
According to the present invention, since the apnea detection device is provided with the storage means and the display means, the date and time determined as the apnea state by the breath determination means is stored by the storage means, and the data is displayed by the display means. Will be. Therefore, there is an effect that the date and time and the number of times the apnea state is detected can be stored and displayed by the apnea detection device itself.
[0064]
Further, the level display function provided in the display means displays the level of the detection signal being detected. Therefore, there is an effect that it can be easily determined whether or not correct detection is performed. Also, if you are in the spot during detection, you can grasp the moment of apnea without any alarm output, which is advantageous in terms of safety. As a result, it is possible to solve the problem that existed in the conventional apnea detection device, that is, the problem that there is no means for confirming the detection signal level being detected and it is difficult to determine whether normal detection is being performed. .
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an apnea detection device according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along the line II-II of the detection mat in the embodiment.
3 is a cross-sectional view taken along line III-III of the detection mat shown in FIG.
FIG. 4 is a front view showing a monitor in the embodiment.
FIG. 5 is a side view showing a monitor in the embodiment.
FIG. 6 is a cross-sectional view showing a pressure sensor in the embodiment.
FIG. 7 is an electric circuit block diagram in the embodiment.
FIG. 8 is a diagram showing pressure fluctuation during respiration detection in the embodiment.
FIG. 9 is a diagram showing all dots on the LCD display in the embodiment.
FIG. 10 is a diagram showing an LCD display after a power key is turned on in the embodiment.
FIG. 11 is a diagram showing an LCD display during an apnea detection mode in the embodiment.
FIG. 12 is a diagram showing switching of each setting mode in the embodiment.
FIG. 13 is a diagram showing an LCD display in a current time setting mode in the embodiment.
FIG. 14 is a diagram showing an LCD display in a time determination value 1 setting mode in the embodiment.
FIG. 15 is a flowchart showing an apnea detection method in the embodiment.
FIG. 16 is a diagram showing an LCD display in a stored data display mode in the embodiment.
FIG. 17 is a diagram showing a relationship between transition between modes and key operations in the embodiment.
[Explanation of symbols]
1 Apnea detection device
10 Detection mat
20 Monitor
21 Pressure sensor
34 E2PROM as time setting means
312 Respiratory determination means
318 RAM as storage means and time setting means
322 Pressure measuring means as detecting means
323 Alarm means
324 display means
A Digital display with data display function and data sort function
Pattern as D level display function and data display function

Claims (4)

Detection means for detecting body movement including respiration of a subject and outputting a detection signal, and respiration for determining an apnea state when a detection value based on the detection signal generated from the detection means is less than a predetermined threshold When it is determined that the subject is in an apnea state by the determination means and the breath determination means, the storage means stores the date and time, and the storage means stores the apnea state determined by the breath determination means for a predetermined time. A time setting means for setting an apnea time for starting the operation, and a display means for displaying the date and time stored by the storage means,
The display means includes a level display function configured to display a detection signal level generated from the detection means ,
The detection means includes a pressure sensing pipe that generates pressure fluctuation in synchronization with body movement including breathing of the subject, a pressure receiving chamber connected to the pressure sensing pipe and receiving pressure, and a back pressure chamber adjacent to the pressure receiving chamber. And a pressure sensor circuit section that partitions the pressure receiving chamber and the back pressure chamber and detects pressure fluctuations of the pressure sensitive pipe,
Wherein the pressure-receiving chamber and the back pressure chamber, apnea detecting apparatus according to claim Rukoto air release aperture is a through hole communicating with the atmosphere are formed respectively. The apnea detection device according to claim 1 , further comprising alarm means for outputting an alarm signal when the apnea state determined by the breath determination means continues for a predetermined time ,
The apnea detection apparatus characterized in that the time setting means individually sets an apnea time when the alarm means outputs an alarm and an apnea time when the storage means starts storing . The apnea detection device according to claim 1 or 2 , wherein the storage unit is configured to be capable of storing a plurality of dates and times, and the display unit has a data display function capable of displaying the number of the plurality of dates and times. An apnea detection device comprising: 4. The apnea detection apparatus according to claim 3 , wherein the data display function includes a data sort function for rearranging the dates and times stored in the storage means in order.

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