JP6999141B1 - Biometric information collection system and sensor unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system for obtaining respiratory rate information, ventilation volume information, heart rate information, blood pressure (cardiac output) information, and body temperature information by a simple configuration. SOLUTION: A flow sensor 21A, 21B and a temperature sensor 22 provided in a breathing flow path, and a transmission unit 27 for transmitting flow data obtained by the flow sensor 21A, 21B and temperature data obtained by the temperature sensor 22 are transmitted. Based on the flow rate data received by the sensor unit 200 provided and the communication unit 355 that receives the flow rate data and the temperature data transmitted from the transmission unit 27, the respiratory rate information, the ventilation volume information, the heart rate information, and the blood pressure (cardiac output). For biometric information generation means that generates body temperature information based on temperature data as well as volume) information, and generated respiratory rate information, ventilation volume information, cardiac output information, blood pressure (cardiac output) information, and body temperature information. It has a central unit 300 including an output control unit 370 that outputs information based on the above. [Selection diagram] Fig. 1

Description

The present invention relates to a biometric information collection system and a sensor unit.

Conventionally, in order to grasp the health condition of a person, for biological information such as body temperature, respiratory rate, blood pressure (or cardiac output) information , a measurement device (sensor) corresponding to each biological information is used. Moreover, only one biometric information is obtained from the information obtained from one measuring device, and it is not possible to easily obtain a plurality of biometric information using the information obtained from one measuring device. ..

Further, when measuring biological information, there is a problem that it is difficult to measure anytime and anywhere under unconstrained conditions. By the way, due to the recent miniaturization of sensor devices, a simple wearable measuring device has been developed, which makes it possible to easily measure biological information such as respiratory rate, heart rate, and body temperature. However, the current wearable measuring device has a problem that it cannot quantitatively measure and evaluate biological information such as respiratory volume and cardiac output. As a result, the use of the wearable measuring device is limited to the monitoring level in daily life, and cannot be applied to medical use that requires highly accurate and quantitative numerical values for biological information.

Patent Document 1 includes a weight sensor, a body temperature sensor, a body fat sensor, a blood type sensor, a blood pressure (heart rate) sensor, a blood glucose sensor, an oxidation saturation sensor, a heart rate sensor, an electrocardiogram sensor, an electrocardiogram sensor, and myoelectricity. It is described that the health condition is grasped by using various sensors such as a figure sensor, an electrocardiogram sensor, and an electric skin reaction sensor.

Patent Document 2 discloses a device that allows another user to experience a user's emotion at the time of recording by using a heart rate sensor, a blood pressure (cardiac output) sensor, a sweating sensor, a body temperature sensor, and the like. ..

Special Table 2013-540454 Japanese Unexamined Patent Publication No. 2017-211862

In the embodiment of the present invention, respiratory rate information, ventilation volume information, heart rate information, blood pressure (or cardiac output) information , and body temperature information can be obtained by a simple configuration.

The biological information collection system according to the embodiment of the present invention is attached to a device arranged in a breathing flow path of an airway or an oral cavity, and is obtained by a flow rate sensor and a temperature sensor provided in the breathing flow path and the flow rate sensor. A sensor unit including a transmission unit for transmitting flow rate data and temperature data obtained by the temperature sensor, a reception unit for receiving flow rate data and temperature data transmitted from the transmission unit, and this receiving unit receive. A biological information generation means that generates respiratory rate information, ventilation volume information, heart rate information, blood pressure (or heart rate output) information based on the flow rate data, and body temperature information based on the temperature data, and the living body. It has a central unit equipped with an output control unit that outputs information based on respiratory rate information, ventilation volume information, heart rate information, blood pressure (or heart rate output) information , and body temperature information generated by the information generation means. The sensor unit has a tubular sensor holder, and a sensor film in which a temperature sensor and two flow sensors are integrated is provided in the cylinder along the diameter of the cylinder in the cylinder portion of the sensor holder. At the same time, a rectifying body composed of a first rectifying plate and a second rectifying plate for rectifying the exhaled air / inhaled air that hits the sensor film is provided, and the first rectifying plate and the second rectifying plate are provided. , It has a plurality of ribs protruding to the sides facing each other, and the facing ribs are in contact with each other at the same position of the sensor film from the front surface and the back surface, and the first rectifying plate and the second rectifying plate are in contact with each other. The space surrounded by the ribs is characterized by forming a breathing flow path .

In the biological information collection system according to the embodiment of the present invention, the device arranged in the respiratory flow path of the oral cavity is characterized by being a medical face mask .

In the biological information collection system according to the embodiment of the present invention, the sensor unit has a flow rate based on a short tube protruding from a device arranged in the airway or the breathing flow path of the oral cavity and a signal obtained by the flow rate sensor. A measurement circuit that measures the signal corresponding to the data, a temperature measurement circuit that measures the signal corresponding to the temperature data based on the signal obtained by the temperature sensor, and the output of the measurement circuit and the output of the temperature measurement circuit are digital. An A / D conversion circuit to be converted and sent to the transmission unit and a printed board on which the transmission circuit is mounted and a hole into which the short tube is inserted are provided, and the printed board is provided. The short tube is provided in the lower case with the short tube inserted, and the lower case is covered with the upper case, so that the user's breath flowing in the sensor unit does not leak to the printed substrate when the sensor unit is used. As described above, an O-ring for sealing the step portion formed at the joint portion between the upper case and the short tube is provided .

In the biological information collection system according to the embodiment of the present invention, the output control unit is a time-series generated respiratory rate information, ventilation volume information, heart rate information, blood pressure (or heart rate output) information , and body temperature information. It is characterized by outputting a graph created based on the value.

The sensor unit according to the embodiment of the present invention has a receiving unit that receives transmitted flow rate data and temperature data, and based on the flow rate data received by this receiving unit, respiratory rate information, ventilation volume information, heart rate information, A biological information generating means that generates blood pressure (or heart rate output) information and also generates body temperature information based on the temperature data, and a respiratory rate information, ventilation volume information, and heart rate information generated by the biological information generating means. A sensor unit that transmits flow rate data and temperature data to a central unit equipped with an output control unit that outputs information based on blood pressure (or heart rate output) information and body temperature information, and is a respiratory flow in the airway or oral cavity. A transmission unit attached to a device arranged on the road and transmitting a flow rate sensor and a temperature sensor provided in the breathing flow path, flow rate data obtained by the flow rate sensor, and temperature data obtained by the temperature sensor, and a transmission unit. The sensor unit has a tubular sensor holder, and a sensor film in which a temperature sensor and two flow sensors are integrated and provided in the cylinder along the diameter of the cylinder in the cylinder portion of the sensor holder. Is provided, and a rectifying body composed of a first rectifying plate and a second rectifying plate for rectifying the exhaled air / intake that hits the sensor film is provided, and the first rectifying plate and the second rectifying plate are provided. The plate has a plurality of ribs protruding to the sides facing each other, and the facing ribs abut on each other at the same position of the sensor film from the front surface and the back surface, and the first rectifying plate and the second The space surrounded by the rectifying plate and the rib is characterized by forming a breathing flow path leading to the breathing flow path of the oral cavity .

In the sensor unit according to the embodiment of the present invention, the device arranged in the respiratory flow path of the oral cavity is a medical face mask .

The sensor unit according to the embodiment of the present invention is characterized in that a support frame for supporting a substrate provided with a flow rate sensor and a temperature sensor is provided in the center of the cylindrical portion of the tubular sensor holder along the longitudinal direction. ..

The sensor unit according to the embodiment of the present invention is characterized by including a mounting portion that can be detachably attached to a medical face mask .

The functional block diagram of the biological information collection system which concerns on embodiment of this invention. The side view which shows the use state of the sensor unit which concerns on embodiment of this invention. The assembled perspective view of the sensor unit which concerns on embodiment of this invention. FIG. 3 is a cross-sectional view of the sensor holder used in the sensor unit according to the embodiment of the present invention on the side of the second case 255B from the joint surface between the first case 255A and the second case 255B. The assembled perspective view of the sensor holder used for the sensor unit which concerns on embodiment of this invention. The figure which shows an example of the waveform displayed in the biological information collection system which concerns on embodiment of this invention. The figure which shows an example of the tracheal intubation tube to which the sensor unit which concerns on embodiment of this invention is connected.

Hereinafter, the biometric information collection system and the sensor unit according to the embodiment of the present invention will be described with reference to the accompanying drawings. In each figure, the same components are designated by the same reference numerals, and duplicate description will be omitted. FIG. 1 shows a functional block diagram of the biological information collection system 100 and the sensor unit 200 according to the embodiment of the present invention.

As shown in FIG. 1, the biometric information collection system 100 has a sensor unit 200 and a central unit 300. The sensor unit 200 includes flow rate sensors 21A and 21B and a temperature sensor 22. The flow rate sensors 21A and 21B and the temperature sensor 22 are composed of a thermal resistance element whose resistance changes depending on the temperature. The flow rate sensor 21A is incorporated in one of the bridge circuits (first bridge circuit) of the gas flow velocity measuring circuit 38 of the international publication WO2016 / 125842, and the flow rate sensor 21A is the gas flow velocity measuring circuit 38 of the international publication WO2016 / 125842. It is incorporated in the other bridge circuit (second bridge circuit).

The measurement circuit 23 to which the flow rate sensors 21A and 21B are connected has the same configuration as the gas flow velocity measurement circuit 38 of International Publication No. WO2016 / 125842. The measurement circuit 23 outputs the output voltage Vout1 of the first bridge circuit, the output voltage Vout2 of the second bridge circuit, and the output voltage Vout of the gas flow velocity measurement circuit 38. The temperature sensor 22 is connected to the temperature measuring circuit 24 to which a constant current is supplied by the constant current circuit. The temperature measurement circuit 24 outputs a voltage generated by the current of the constant current circuit flowing through the temperature sensor 22.

Since the output of the measurement circuit 23 can be used for flow rate calculation, it is referred to as flow rate data in this embodiment. The flow rate data, which is the output of the measurement circuit 23, is digitized by the A / D conversion circuit 25 and sent to the transmission unit 27. The temperature data, which is the output of the temperature measurement circuit 24, is also digitized by the A / D conversion circuit 26 and sent to the transmission unit 27.

The central unit 300 is realized by a computer system similar to that of a personal computer system. That is, the central unit 300 is a computer system in which the CPU 310 performs necessary operations using the programs and data of the main memory 320 and controls each unit. The CPU 310 is connected to the external storage controller 340, the communication controller 350, the input controller 360, and the output controller 370 via the bus 330.

An external storage device 345 is connected to the external storage controller 340. The external storage device 345 stores programs and data used by the CPU 310, and the CPU 310 can read necessary programs and data into the main memory 320 and control operations and parts using the programs and data.

A communication unit 355 including a receiving unit and a transmitting unit is connected to the communication controller 350. The flow rate data and the temperature data sent from the transmission unit 27 are received by the communication unit 355, and the CPU 310 can capture the flow rate data and the temperature data via the communication controller 350.

An input device 365 composed of a keyboard and a touch panel for inputting information, a mouse as a pointing device, and the like is connected to the input controller 360. A computer system can be operated by inputting a command, data, or the like from the input device 365.

Various display devices such as LEDs and an output device 375 such as a printer are connected to the output controller 370. The CPU 310 can output (display or print out) necessary biometric information or the like in characters or in a graph from the output device 375.

As shown in FIG. 2, the sensor unit 200 of the present embodiment is attached to a medical face mask 500, which is a device arranged in the respiratory tract of the respiratory tract or the oral cavity. 220 in FIG. 3 is a mask fixing component. The mask mounting component 220 has a ring portion 221 having a diameter that slides along the outer circumference thereof in a state of being relatively tightly fitted to the outer wall of the short tube 210 protruding from the central portion of the medical face mask 500 shown in FIG. Be prepared. An arm 222 is provided so as to project from the peripheral edge of the ring portion 221 every 1/4 lap, and a hook 223 protruding in a direction away from the medical face mask 500 is formed at the tip of the arm 222.

230 is a lower case. The lower case 230 has a dish shape and is formed by raising the peripheral edge, and a hole 231 into which the short tube 210 is inserted is formed in the central portion. Further, inside the lower case 230, a printed circuit board 232 formed in a donut disc shape is provided. The printed circuit board 232 is provided with a measurement circuit 23, a temperature measurement circuit 24, A / D conversion circuits 25 and 26, and a transmission unit 27.

240 is the upper case. The upper case 240 functions as a lid of the lower case 230, has a dish shape corresponding to the lower case 230, is formed by raising the peripheral edge, and the short tube 210 is inserted in the central portion. The hole portion 241 is formed. A holder receiving wall 243 is provided from the peripheral edge of the hole 241 so that a slight step 242 is formed on the upper peripheral edge of the hole 241.

The holder receiving wall 243 has a shape that can accept the sensor holder 250 having a shape in which a rectangular parallelepiped is connected to a cylinder, and is basically a cylinder, and a part of the cylinder is cut out. A guide 244 is formed so that the rectangular parallelepiped portion of the holder receiving wall 243 can be arranged from the notched portion toward the peripheral edge of the upper case 240.

An O-ring 270 is interposed in the step portion 242 of the upper case 240. By accommodating the sensor holder 250 with respect to the holder receiving wall 243 from above in this state, the space between the bottom peripheral edge of the cylindrical portion of the holder receiving wall 243 and the step portion 242 is sealed by the O-ring 270, and the sensor unit When the 200 is used, the contamination of the substrate 232 due to the leakage of the user's breath to the substrate 232 is prevented, and accurate measurement is possible.

As shown in FIGS. 4 and 5, the sensor unit 200 has, for example, a cylindrical sensor holder 250, and a flow rate sensor and a temperature sensor are provided along the longitudinal direction of the cylindrical portion of the sensor holder 250. As a specific example, the exhaled air / intake air corresponding to the sensor film 901 provided by integrating the flow rate sensors 21A and 21B and the temperature sensor 22 is rectified in the cylinder along the diameter of the cylinder in the cylindrical portion of the sensor holder 250. A rectifying body 251 composed of rectifying plates 251A and 251B for the purpose is provided. One of the flow rate sensor 21A and the flow rate sensor 21B is provided on the side of the sensor film 901 far from the mask, and the other is provided on the side close to the mask. The straightening vane 251A and the straightening vane 251B have a plurality of ribs 52 protruding toward the sides facing each other. The facing ribs 52 are in contact with each other at the same positions of the sensor film 901 and the insulating plate 902 from the front surface and the back surface, and the space surrounded by the straightening vanes 251A and 251B and the rib 52 constitutes a breathing flow path. The flow rate sensors 21A and 21B may have a structure provided on the inner wall of the cylinder of the cylindrical sensor holder 250.

The sensor film 901 is connected to a printed circuit board 232 on which the measurement circuit 23 of FIG. 1 and the temperature measurement circuit 24 of FIG. 1 are mounted via a U-shaped relay board 903 and a connector 904. The sensor holder 250 includes a casing in which a first case 255A and a second case 255B, which are obtained by bisecting a case formed by connecting a rectangular parallelepiped from a side to a cylinder, are combined. The first case 255A includes a straightening vane 251A, and the second case 255B includes a straightening vane 251B. In the rectangular parallelepiped portion of the first case 255A and the second case 255B, a boss 252 having a concave portion and a convex portion formed at the tip portion is formed at positions facing each other, and the boss 252 passes through a hole of the relay board 903. By being coupled to each other, the sensor 900 is fixed.

A packing 254 is interposed at the boundary between the cylindrical portion and the rectangular parallelepiped portion of the first case 255A and the second case 255B to prevent breathing from leaking from the cylindrical portion to the rectangular parallelepiped portion, and to perform high-precision measurement. Guaranteed. The restraining plates 256 and 256 provided at the ends of the first case 255A are fitted between the holding pieces 255 and 258 provided near the ends of the second case 255B and are fitted between the first case 255A and the first case 255A. Case 255B of 2 is combined. The illustrated recess 259B provided on the outer wall of the cylindrical portion of the second case 255B and the recess 259A (not shown) provided on the outer wall of the cylindrical portion of the first case 255A at the corresponding positions of the recess 259B. Is elastically pressed by the claw piece 245 (FIG. 3) formed at the corresponding position of the holder receiving wall 243 of the upper case 240, and the sensor holder 250 is fixed to the upper case 240.

The sensor unit 200 assembled as described above is provided with the flow rate sensors 21A and 21B and the temperature sensor 22 of FIG. 1 integrated, and is a rectifying body 251 composed of rectifying plates 251A and 251B (FIG. 3). Consists of the respiratory flow path. As described above, the sensor unit 200 including the flow rate sensors 21A and 21B and the temperature sensor 22 is attached to the mask 500, which is a device arranged in the respiratory tract of the airway or the oral cavity.

As shown in FIG. 1, the flow rate data and the temperature data measured by the sensor unit 200, digitized and sent from the transmission unit 27 shown in FIG. 1 are received and communicated by the communication unit 355 of the central unit 300. The CPU 310 takes in the data via the controller 350. The CPU 310 converts temperature data, which is a voltage, into temperature information using, for example, a voltage-temperature conversion table, sends it to the output controller 370, and outputs it from the output device 375.

As already described, the flow rate data are the output voltage Vout1 of the first bridge circuit, the output voltage Vout2 of the second bridge circuit, and the output voltage Vout of the gas flow velocity measuring circuit 38. Based on this, it is published in International Publication WO2016 / 125842 to obtain a waveform indicating the direction of gas flow in the outward and reverse directions in the respiratory flow path of the airway or the oral cavity, that is, to obtain the waveform of one respiratory cycle. There is. The CPU 310 can obtain the respiratory rate information and the ventilation volume information which is a quantitative change of the air flow by obtaining the waveform of one breathing frequency by this method.

Obtaining a gas flow rate based on the above flow rate data is published in International Publication WO2016 / 125842, and describes that a heartbeat signal showing a heartbeat waveform is extracted from a breathing signal. Data and the like necessary for this method are stored in an external storage device 345, and the CPU 310 can use this to obtain heart rate information.

The biological information collection system 100 according to the present embodiment obtains and outputs blood pressure (or cardiac output) information . Heart rate and blood pressure (cardiac output) can be analyzed as follows. The sensor unit 200 measures changes in physical quantities, and the obtained heart rate (times / minute) and cardiac output (mL / min) have the following relationship.
Cardiac output (mL / min) = Stroke volume (mL) x Heart rate (times / min)
The change in physical quantity with the heartbeat movement obtained by this flow rate sensor reflects the cardiac output, and the relative evaluation of "stroke volume (mL)" can be performed. in short,
Cardiac output (mL / min) ∝
[Volume change (mL) due to contraction of the heart obtained by this flow sensor] x heart rate (times / minute)
The relationship holds.

On the other hand, blood pressure has a relationship between cardiac output (mL / min) and peripheral vascular resistance (mmHg / (mL / min)) as follows.
Blood pressure = cardiac output (mL / min) x peripheral vascular resistance (mmHg / (mL / min))
"Peripheral vascular resistance (mmHg / (mL / min)" cannot be measured by this flow sensor, but between blood pressure and cardiac output, blood pressure ∝ [Volume change due to cardiac contraction obtained by this flow sensor (mL)] x Cardiac output (times / minute) x Peripheral vascular resistance, that is, blood pressure ∝ [Volume change with contraction of the heart obtained by this flow sensor (mL)]
[Volume change (mL) with contraction of the heart obtained by this flow sensor] reflects the fluctuation of blood pressure.

Therefore, the CPU 310 deletes the respiration-based component from the flow rate data, obtains [volume change (mL) accompanying the contraction of the heart obtained by this flow rate sensor], and based on this, changes in blood pressure (cardiac output). Shall be sought. What is obtained in this way is referred to as blood pressure (or cardiac output) information. As described above, the CPU 310 generates respiratory rate information, ventilation volume information, heart rate information, and blood pressure (or heart rate output) information based on the flow rate data received by the receiving unit (communication unit 355), and described above. It functions as a biological information generation means for generating body temperature information based on temperature data. The output controller 370, which is an output control unit that outputs information based on the respiratory rate information, ventilation volume information, heart rate information, blood pressure (or heart rate output) information , and body temperature information generated by the CPU 310 as the biological information generation means. It is sent to the output device 375 and output by the output controller 370.

The CPU 310 of the present embodiment can create and output a graph based on the values of respiratory rate information, ventilation volume information, heart rate information, blood pressure (or cardiac output) information , and body temperature information generated in time series. can. For example, the information on the respiratory flow rate is output as a graph as shown in FIG. 6 so that the respiratory rate can be known.

In the above embodiments, the device arranged in the respiratory tract of the airway or the oral cavity has been described as a medical face mask, but this device is a tracheal intubation tube 700 as shown in FIG. 7, and in some cases, a medical nose. It may be a mask. The tracheal intubation tube 700 mainly includes a tube 710 to be inserted into the trachea and a cuff 720 provided near the tip of the tube 710. Air is sent to the cuff 720 to inflate the cuff 720 via the inflation line 730. The configuration of FIG. 7 is only an example, and for example, in the middle part of tracheal intubation for children, there are some that are not provided with a cuff.

A pilot balun 740 is connected to the inflation line 730, and the degree of swelling of the cuff 720 can be monitored. A syringe (not shown) for sending air is provided on the tip side of the pilot balun 740. The mouth side of the tube 710 is a connector 750, and the sensor unit 200 is connected to this connector 750. That is, the connector 750 corresponds to the short tube 210. Even if the sensor unit 200 is connected to the tracheal intubation tube 700 for measurement, respiratory rate information, ventilation volume information, heart rate information, blood pressure (or cardiac output) information , and body temperature information can be obtained by a simple configuration. Can be done.

21A Flow sensor 21B Flow sensor 22 Temperature sensor 23 Measurement circuit 24 Temperature measurement circuit 25, 26 A / D conversion circuit 27 Transmitter 100 Biometric information collection system 200 Sensor unit 210 Short tube 220 Mask mounting part 230 Lower case 240 Upper case 250 Sensor Holder 251 Rectifier 251A, 251B Rectifier board 255A First case 255B Second case 270 O-ring 300 Central unit 320 Main memory 330 Bus 340 External storage controller 345 External storage device 350 Communication controller 355 Communication unit 360 Input controller 365 Input device 370 Output Controller 375 Output Device 500 Medical Face Mask 700 Tracheal Intubation Tube

Claims (8)

A flow sensor and a temperature sensor attached to a device arranged in the breathing flow path of the airway or the oral cavity and provided in the breathing flow path, and the flow rate data obtained by the flow rate sensor and the temperature data obtained by the temperature sensor are obtained. A sensor unit with a transmitter to transmit,
Respiratory rate information, ventilation volume information, heart rate information, blood pressure (or heart rate output ) based on the receiving unit that receives the flow rate data and temperature data transmitted from the transmitting unit and the flow rate data received by this receiving unit. ) Biological information generation means that generates body temperature information based on the temperature data as well as information, and respiratory rate information, ventilation volume information, heart rate information, blood pressure (or heart rate output ) generated by the biometric information generation means. ) It has a central unit equipped with an output control unit that outputs information based on information and body temperature information.
The sensor unit has a cylindrical sensor holder, and the inside of the cylinder is formed along the diameter of the cylinder in the cylinder portion of the sensor holder.
A sensor film in which a temperature sensor and two flow rate sensors are integrated is provided, and at the same time, a sensor film is provided.
A rectifying body composed of a first rectifying plate and a second rectifying plate for rectifying the exhaled air / inhaled air that hits the sensor film is provided.
The first straightening vane and the second straightening vane have a plurality of ribs protruding to the sides facing each other, and the facing ribs abut against each other at the same position of the sensor film from the front surface and the back surface. A biometric information collection system characterized in that a space surrounded by the first straightening vane, the second straightening vane, and ribs constitutes a breathing flow path . The biometric information collection system according to claim 1, wherein the device arranged in the respiratory flow path of the oral cavity is a medical face mask . The sensor unit has
A short tube protruding from a device located in the airway or the respiratory channel of the oral cavity,
A measurement circuit that measures a signal corresponding to the flow rate data based on the signal obtained by the flow sensor, a temperature measurement circuit that measures a signal corresponding to the temperature data based on the signal obtained by the temperature sensor, and an output of the measurement circuit. The A / D conversion circuit that digitizes the output of the temperature measurement circuit and sends it to the transmission unit, and the printed board on which the transmission circuit is mounted and a hole into which the short tube is inserted are formed.
Be prepared,
The printed circuit board is provided in the lower case with the short tube inserted, and the lower case is covered with the upper case.
An O-ring is provided to seal the step portion formed at the joint portion between the upper case and the short tube so that the user's breath flowing through the sensor unit does not leak to the printed circuit board when the sensor unit is used. The biometric information collection system according to claim 1 or 2. The output control unit is characterized by outputting a graph created based on the values of respiratory rate information, ventilation volume information, heart rate information, blood pressure (or heart rate output) information , and body temperature information generated in time series. The biometric information collection system according to claim 1 or 2 . Based on the receiving unit that receives the transmitted flow rate data and temperature data, and the flow rate data received by this receiving unit, it generates breath rate information, ventilation volume information, heart rate information, and blood pressure (or heart rate output) information . At the same time, the biological information generation means that generates body temperature information based on the temperature data, and the respiratory rate information, ventilation volume information, heart rate information, blood pressure (or heart rate output) information , and body temperature generated by the biological information generation means. A sensor unit that transmits flow data and temperature data to a central unit equipped with an output control unit that outputs information based on information.
A flow rate sensor and a temperature sensor attached to a device placed in the respiratory tract of the airway or the oral cavity and provided in the respiratory tract,
A transmission unit for transmitting flow rate data obtained by the flow rate sensor and temperature data obtained by the temperature sensor is provided.
The sensor unit has a cylindrical sensor holder, and the inside of the cylinder is formed along the diameter of the cylinder in the cylinder portion of the sensor holder.
A sensor film in which a temperature sensor and two flow rate sensors are integrated is provided, and at the same time, a sensor film is provided.
A rectifying body composed of a first rectifying plate and a second rectifying plate for rectifying the exhaled air / inhaled air that hits the sensor film is provided.
The first straightening vane and the second straightening vane have a plurality of ribs protruding to the sides facing each other, and the facing ribs abut against each other at the same position of the sensor film from the front surface and the back surface. A sensor unit characterized in that a space surrounded by the first straightening vane, the second straightening vane, and ribs constitutes a breathing flow path following the breathing flow path of the oral cavity . The sensor unit according to claim 5, wherein the device arranged in the respiratory flow path of the oral cavity is a medical face mask . The sensor unit according to claim 5 or 6, wherein a support frame for supporting a substrate provided with a flow rate sensor and a temperature sensor is provided at the center of a cylindrical portion of the tubular sensor holder along the longitudinal direction. The sensor unit according to claim 6, further comprising a mounting portion that can be detachably attached to the medical face mask .

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