CN217488637U - Wearable multi-parameter monitoring equipment - Google Patents

Abstract

The utility model relates to a wearing formula multi-parameter guardianship equipment, including the body temperature probe, the body temperature probe has multi-parameter measuring unit through a first cable electric connection, and multi-parameter measuring unit has main measuring unit through a second cable electric connection, and main measuring unit communication connection has the monitor host computer. The utility model discloses an all integrate the measuring unit of electrocardio, breathing, body temperature, blood oxygen and pulse rate to the multi-parameter measuring unit in, again through with the multi-parameter measuring unit with a second cable junction with main measuring unit, carried out wearable multi-parameter supervisory equipment's integral type design, reducible a large amount of cable is connected, solved easy winding between the clinical use cable, doctor's work is loaded down with trivial details, patient experience is poor, restriction patient activity and free shortcoming.

Description

Wearable multi-parameter monitoring equipment

Technical Field

The utility model relates to a wearing formula multi-parameter guardianship equipment, especially a wearing formula multi-parameter guardianship equipment.

Background

The multi-parameter monitor provides important patient information for medical clinical diagnosis, and can detect important parameters of human body such as electrocardiosignals, heart rate, blood oxygen saturation, blood pressure, respiration and body temperature in real time through various functional modules, so as to realize supervision and alarm of the parameters. In the monitoring equipment in the current market, when monitoring human parameters, the probe of each parameter is connected with the host computer in a wired mode, such as: the blood pressure is measured and is linked to each other cuff and host computer through an trachea, measure blood oxygen, body temperature, breathe and pulse rate and link to each other corresponding probe and host computer through a cable, consequently there are too many cable connections between host computer and the human body, easily twine during guardianship between the cable, the cable is connected too much and is leaded to using complicacy, the poor stability, require the high complex operation of skill degree to medical personnel, it is poor to experience the patient, too much wire connection leads to patient's inadaptation, easy health removes and leads to the measured data deviation, patient's activity and freedom have also been restricted, especially to the child of mobility more to monitor the difficulty.

SUMMERY OF THE UTILITY MODEL

To current not enough, the utility model provides a wearing formula multi-parameter guardianship equipment.

The utility model provides a technical scheme that its technical problem adopted is: the utility model provides a wearing formula multi-parameter guardianship equipment, includes body temperature probe, body temperature probe has multi-parameter measuring unit through a first cable electric connection, multi-parameter measuring unit has main measuring unit through a second cable electric connection, main measuring unit communication connection has the monitor host computer.

Preferably, the body temperature probe comprises a metal shell, a heat-conducting resin block arranged in the metal shell, and an NTC temperature sensor arranged in the heat-conducting resin block, wherein the NTC temperature sensor and the metal shell are both electrically connected with the multi-parameter measuring unit.

Preferably, the multi-parameter measuring unit comprises a first shell made of stainless steel and a first control circuit board arranged in the first shell, the first shell is electrically connected with the body temperature probe, the first control circuit board is electrically connected with the main measuring unit, and a signal acquisition module is arranged on the first control circuit board.

Preferably, a reflective sensor electrically connected with the first control circuit board and used for measuring the blood oxygen saturation is arranged at the bottom of the first shell.

Preferably, a first pressure sensor electrically connected with the first control circuit board and used for detecting respiration is arranged at the bottom of the first shell or an acceleration sensor used for detecting respiration is arranged on the first control circuit board.

Preferably, the main measurement unit comprises a cuff and a second casing installed on the cuff, a second control circuit board, an air pump, an electromagnetic valve and a battery are arranged in the second casing, the air pump, the electromagnetic valve and the battery are all electrically connected with the second control circuit board, the air pump is communicated with the cuff in a sealing mode, the electromagnetic valve is arranged between the air pump and the cuff, a cuff pressing block is arranged at the bottom of the second casing, a second pressure sensor is arranged at the bottom of the second control circuit board, and the second pressure sensor is electrically connected with the second control circuit board.

Preferably, the main measuring unit is in wired communication connection with the monitor host through a third cable, and a socket matched and plugged with a plug connector of the third cable is arranged on the monitor host.

Preferably, a charging seat is arranged on the monitor host, and a charging module matched with the charging seat is arranged on the main measuring unit.

As preferred, the multi-parameter measurement unit is including the ear clip formula blood oxygen probe that is used for detecting oxyhemoglobin saturation and pulse rate, the respiratory measurement unit that is used for detecting breathing, ear clip formula blood oxygen probe and respiratory measurement unit all with main measuring unit electric connection, be provided with the transmission type light sensor with main measuring unit electric connection in the ear clip formula blood oxygen probe, respiratory measurement unit includes the bandage, sets up the respiratory detection probe in bandage one end, be provided with a plurality of button holes on the bandage, be provided with on the respiratory detection probe and match the bandage of lock with the button hole and buckle.

As preferred, main measuring unit electric connection has ring formula blood oxygen probe, ring formula blood oxygen probe is the annular ring formula blood oxygen probe of cavity finger, ring formula blood oxygen probe is reflection formula blood oxygen probe or transmission formula blood oxygen probe, reflection formula blood oxygen probe includes reflection formula casing, sets up the reflection formula PCB in the reflection formula casing, be provided with reflection formula transmitting tube, reflection formula receiver tube on the reflection formula PCB, transmission formula blood oxygen probe includes transmission formula casing, sets up first transmission formula PCB and the second transmission formula PCB in the transmission formula casing, first transmission formula PCB and second transmission formula PCB electric connection just set up the upper and lower both ends at the transmission formula casing relatively, be provided with the transmission formula receiver tube on the first transmission formula PCB, be provided with the transmission formula transmitter tube on the second transmission formula PCB.

The beneficial effects of the utility model reside in that: the utility model discloses an all integrate the measuring unit of electrocardio, breathing, body temperature, blood oxygen and pulse rate to the multi-parameter measuring unit in, again through with the multi-parameter measuring unit with a second cable junction with main measuring unit, carried out wearable multi-parameter supervisory equipment's integral type design, reducible a large amount of cable is connected, solved easy winding between the clinical use cable, doctor's work is loaded down with trivial details, patient experience is poor, restriction patient activity and free shortcoming.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural view of a body temperature probe according to an embodiment of the present invention;

FIG. 3 is a schematic cross-sectional view of a multi-parameter measuring unit according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a multi-parameter measuring unit according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a main measurement unit according to an embodiment of the present invention;

fig. 6 is a schematic structural view of a third cable according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a monitor host according to an embodiment of the present invention;

FIG. 8 is a schematic view of an embodiment of the present invention illustrating an ear clip type blood oxygen probe;

fig. 9 is a schematic structural diagram of a respiration measurement unit according to an embodiment of the present invention;

FIG. 10 is a schematic view of a ring-shaped blood oxygen probe according to an embodiment of the present invention;

FIG. 11 is a schematic view of a reflection type blood oxygen probe according to an embodiment of the present invention;

FIG. 12 is a schematic view of a transmission type blood oxygen probe according to an embodiment of the present invention;

part names and serial numbers in the figure: 1-body temperature probe 11-metal shell 12-heat conducting resin block 13-NTC temperature sensor 2-first cable 3-multi-parameter measuring unit 31-first shell 32-first control circuit board 33-signal acquisition module 34-reflection type sensor 341-transmitting part 342-receiving part 35-first pressure sensor 36-acceleration sensor 37-ear clip type blood oxygen probe 38-respiration measuring unit 381-bandage 3811-buttonhole 382-respiration detecting probe 3821-bandage buckle 39-ear plug type body temperature probe 4-second cable 5-main measuring unit 51-cuff 52-second shell 521-upper shell 522-lower shell 53-second control circuit board 54-air pump 55-electromagnetic valve 56-press block 57-second pressure sensor 58-press key 59-finger ring type blood oxygen probe Oxygen probe 591-reflective blood oxygen probe 5911-reflective housing 5912-reflective PCB 5913-reflective transmitting tube 5914-reflective receiving tube 592-transmissive blood oxygen probe 5921-transmissive housing 5922-first transmissive PCB 5923-second transmissive PCB 5924-transmissive receiving tube 5925-transmissive transmitting tube 6-monitor host 61-socket 62-charging dock 7-third cable.

Detailed Description

To more clearly illustrate the objects, technical solutions and advantages of the embodiments of the present invention, the present invention will be further described in conjunction with the accompanying drawings and embodiments, which are described in a clear and complete manner. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention. Thus, the following detailed description of the embodiments of the invention, as presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "front", "rear", "inner", "outer", etc. indicate the position or positional relationship based on the position or positional relationship shown in the drawings, or the position or positional relationship which is usually placed when the product of the present invention is used, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element to which the term refers must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, should not be construed as limiting the invention, and the terms "first", "second", "third", etc. are only used for distinguishing the description, and should not be construed as indicating or implying relative importance.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; either directly or indirectly through intervening media, or through the communication between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the invention. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

The embodiment of the utility model is shown in figures 1 to 12, a wearable multi-parameter monitoring device, which comprises a body temperature probe 1, the body temperature probe 1 is electrically connected with a multi-parameter measuring unit 3 through a first cable 2, the multi-parameter measuring unit 3 is electrically connected with a main measuring unit 5 through a second cable 4, the main measuring unit 5 is in communication connection with a monitor host 6, when in use, the body temperature probe 1 is placed under the armpit of a person, the multi-parameter measuring unit 3 is pasted at the pectoralis major muscle under the clavicle of the person, preferably, the pasting modes of the multi-parameter measuring unit 3 are two, firstly, back condensation silica gel is arranged around the multi-parameter measuring unit 3, the back condensation silica gel can be directly pasted on the human body, secondly, the multi-parameter measuring unit 3 is pasted on the human body by utilizing medical non-woven fabric adhesive tape, the main measuring unit 5 is tied on the left arm of the person, the body temperature probe 1 is connected with the multi-parameter measuring unit 3 through the first cable 2, the multi-parameter measuring unit 3 and the main measuring unit 5 are connected through a second cable 4, and the main measuring unit 5 and the monitor host 6 can be connected through wireless communication or wired communication.

In a further improvement, as shown in fig. 1 and fig. 2, the body temperature probe 1 includes a metal housing 11, a heat conductive resin block 12 disposed in the metal housing 11, and an NTC temperature sensor 13 disposed in the heat conductive resin block 12, wherein the NTC temperature sensor 13 and the metal housing 11 are both electrically connected to the multi-parameter measuring unit 3, and preferably, the body temperature probe 1 is connected to the multi-parameter measuring unit 3 through a first cable 2, the first cable 2 has three wires, two of the wires are signal wires of the NTC temperature sensor 13, and perform signal acquisition and calculation through the multi-parameter measuring unit 3 to obtain body temperature data, and the other wire is connected to the metal housing 11 of the body temperature probe 1 to serve as one of the measuring electrodes for electrocardiographic detection, that is, the body temperature data can be transmitted to the multi-parameter measuring unit 3 through only one first cable 2.

In a further improvement, as shown in fig. 1 to 4, the multiparameter measuring unit 3 includes a first casing 31 made of stainless steel, a first control circuit board 32 disposed in the first casing 31, the first casing 31 is electrically connected to the body temperature probe 1, the first control circuit board 32 is electrically connected to the main measuring unit 5, a signal collecting module 33 is disposed on the first control circuit board 32, preferably, an electrocardio, respiration, body temperature, blood oxygen and pulse rate signal collecting and calculating circuit is disposed in the signal collecting module 33 on the first control circuit board 32, when in use, the first casing 31 made of stainless steel is in contact with the body surface of a human body, the first casing 31 serves as another electrode for electrocardio detection, the electrode and the metal casing 11 of the body temperature probe 1 form a single-lead electrocardio for measuring the electrocardio signals of the human body to obtain the electrocardio waveforms and the heart rate, the multiparameter measuring unit 3 is connected to the main measuring unit 5 through a second cable 4, the main measuring unit 5 supplies power to the multi-parameter measuring unit 3 through the second cable 4, that is, the multi-parameter measuring unit 3 can transmit the measurement data of the electrocardio, the respiration, the body temperature, the blood oxygen and the pulse rate to the main measuring unit 5 through only one second cable 4.

In a further improvement, as shown in fig. 3 and 4, a reflective sensor 34 electrically connected to the first control circuit board 32 is disposed at the bottom of the first casing 31 for measuring the blood oxygen saturation, when in use, the reflective sensor 34 is disposed at a side close to the human body, and a transmitting portion 341 and a receiving portion 342 are disposed on the reflective sensor 34, preferably, the reflective sensor 34 integrates transmitting, receiving, data conversion and filtering, so as to greatly reduce the system space volume, and the obtained data is used for obtaining the blood oxygen saturation and the pulse rate by an algorithm.

In a further improvement, as shown in fig. 1, 3 and 4, a first pressure sensor 35 electrically connected to the first control circuit board 32 and used for detecting respiration is disposed at the bottom of the first casing 31, or an acceleration sensor 36 for detecting respiration is disposed on the first control circuit board 32, both of which can detect respiration data, when the multiparameter measuring unit 3 is fixed on the pectoralis major muscle, the first pressure sensor 35 is disposed, the first pressure sensor 35 is attached to the pectoralis major muscle, and the respiration change of the thorax acts on the first pressure sensor 35, so that the first pressure sensor 35 can sense the pressure change of the thorax on the first pressure sensor 35 from the respiration change of the thorax, and the respiration frequency is obtained by calculating the periodic pressure change; secondly, an acceleration sensor 36 is arranged on the first control circuit board 32 of the multi-parameter measuring unit 3, and the respiratory frequency can be obtained by measuring the change of the respiratory thorax amplitude.

In a further modification, as shown in fig. 1 and 5, the main measurement unit 5 includes a cuff 51 and a second casing 52 mounted on the cuff 51, a second control circuit board 53, an air pump 54, an electromagnetic valve 55 and a battery are disposed in the second casing 52, the air pump 54, the electromagnetic valve 55 and the battery are all electrically connected to the second control circuit board 53, the air pump 54 is in sealed communication with the cuff 51, the electromagnetic valve 55 is disposed between the air pump 54 and the cuff 51, a cuff press block 56 is disposed at the bottom of the second casing 52, a second pressure sensor 57 is disposed at the bottom of the second control circuit board 53, the second pressure sensor 57 is electrically connected to the second control circuit board 53, that is, the main measurement unit 5 has a function of measuring blood pressure, preferably, the second casing 52 includes an upper casing 521 and a lower casing 522, the electromagnetic valve 55, the air pump 54, the second control circuit board 53 and the battery are all fixed on the lower casing 522, the cuff pressing block 56 is arranged at the bottom end of the lower shell 522, the second pressure sensor 57 is arranged at the bottom of the second control circuit board 53, the upper shell 521 is provided with a button 58 which is electrically connected with the second control circuit board 53 and used for opening and closing the main measuring unit 5, preferably, the second control circuit board 53 is electrically connected with a wireless communication module, the wireless communication module is in wireless communication connection with the monitor host 6, the wireless communication module is a Wi-Fi module, a Bluetooth module, a 2.4G wireless module, one or more of 433M wireless modules, that is, the main measuring unit 5 can transmit the measurement results of electrocardio, respiration, body temperature, blood pressure, blood oxygen and heart rate to the monitor host 6 through the wireless communication module.

In a further improvement, as shown in fig. 1, 6 and 7, the main measuring unit 5 is connected to the monitor host 6 through a third cable 7 in a wired communication manner, a socket 61 that is matched and plugged with a plug of the third cable 7 is provided on the monitor host 6, that is, no battery or wireless communication module is provided on the main measuring unit 5, the main measuring unit 5 is connected to the monitor host 6 through the third cable 7, a socket 61 is provided at the end of the monitor host 6, the main measuring unit 5 is plugged into the socket 61 of the monitor host 6 through the third cable 7, the monitor host 6 supplies power to the main measuring unit 5 and the multi-parameter measuring unit 3 through the third cable 7, the main measuring unit 5 sends the measurement results of electrocardio, respiration, body temperature, blood pressure, blood oxygen and heart rate to the monitor host 6 through the third cable 7, that is, the main measuring unit 5 is connected to the monitor host 6 through a wired communication manner, preferably, the plug data communication interface of the third cable 7 may be a serial port, RS485, CAN or USB.

In a further improvement, as shown in fig. 1 and 7, a charging seat 62 is disposed on the monitor host 6, a charging module adapted to the charging seat 62 is disposed on the main measurement unit 5, and the main measurement unit 5 can be charged by disposing the charging seat 62 on the monitor host 6.

Further improvement, as shown in fig. 8 and fig. 9, the utility model also includes another wearable structure, the multi-parameter measuring unit 3 includes an ear clip type blood oxygen probe 37 for detecting blood oxygen saturation and pulse rate, a respiration measuring unit 38 for detecting respiration, the ear clip type blood oxygen probe 37 and the respiration measuring unit 38 are both electrically connected with the main measuring unit 5, a transmission type optical sensor electrically connected with the main measuring unit 5 is arranged in the ear clip type blood oxygen probe 37, the respiration measuring unit 38 includes a bandage 381, a respiration detecting probe 382 arranged at one end of the bandage 381, a plurality of button holes 3811 are arranged on the bandage 381, a bandage button 3821 matched and buckled with the button holes 3811 is arranged on the respiration detecting probe 382, further preferably, the body temperature probe is an ear type body temperature probe 39, when in use, the main measuring unit 5 is arranged on the left hand arm of the human body, the ear type body temperature probe 39 is arranged in the cochlea of the patient, the ear clip type blood oxygen probe 37 is clipped on the ear lobe of a patient, the transmission type optical sensor comprises a transmitting end and a receiving end, data received by the transmission type optical sensor are processed and calculated on the main measuring unit 5, the blood oxygen saturation and the pulse rate are obtained through a software algorithm, the respiration measuring unit 38 is placed in the chest or the armpit of the patient through the bandage 381, that is, the respiration detecting probe 382 does not need to be contacted with the skin of the human body, the respiration detecting probe 382 can be placed in the armpit or the chest of the human body through clothes, one button eye 3811 at one end of the bandage 381 is clipped on the bandage buckle 3821 of the respiration detecting probe 382, after the bandage 381 surrounds the chest of the patient for a circle, the button eye 3811 at the other end is clipped on the bandage buckle 3821 of the respiration detecting probe 382, the respiration detecting probe 382 can be fixed, and it is further preferable that the measurement schemes of the respiration detecting probe 382 are two, one scheme is on the bottom shell of the respiration detecting probe 382, the surface close to the human body is provided with a pressure sensor, the pressure sensor can sense the pressure change acted on the pressure sensor caused by the respiration change of the thorax, and the respiration frequency is obtained by calculating the change of the periodic pressure; the other is that the respiration detecting probe 382 is internally provided with an acceleration sensor, the respiration frequency can be obtained by measuring the change of the respiration thorax amplitude, and the wearable multi-parameter monitoring device can be measured under the condition of separating from clothes, thereby greatly improving the monitoring experience of patients and reducing the workload of clinical medical care personnel.

In a further improvement, as shown in fig. 10 to fig. 12, the present invention further includes another wearable structure, the main measuring unit 5 is electrically connected to a ring type blood oxygen probe 59, the ring type blood oxygen probe 59 is a ring type blood oxygen probe 59 with a hollow ring shape, the ring type blood oxygen probe 59 is a reflection type blood oxygen probe 591 or a transmission type blood oxygen probe 592, the reflection type blood oxygen probe 591 includes a reflection type housing 5911 and a reflection type PCB5912 disposed in the reflection type housing 5911, the reflection type PCB5912 is provided with a reflection type transmitting tube 5913 and a reflection type receiving tube 5914, the transmission type blood oxygen probe 592 includes a transmission type housing 5921, a first transmission type PCB5922 and a second transmission type PCB5923 disposed in the transmission type housing 5921, the first transmission type PCB5922 is electrically connected to the second transmission type PCB5923 and is disposed at the upper and lower ends of the transmission type housing 5921 relatively, the first transmission type PCB 5924 is disposed on the first transmission type PCB5922, a transmission type transmitting tube 5925 is arranged on the second transmission type PCB5923, that is to say, the ring type blood oxygen probe 59 is a ring type blood oxygen probe 59 with a ring-shaped hollow structure, when the ring type blood oxygen probe 59 is used, the ring type blood oxygen probe 59 is worn on a finger of a person, the ring type blood oxygen probe 59 is connected with the main measuring unit 5 through a cable, the ring type blood oxygen probe 59 is divided into a reflection type and a transmission type, the PCB is arranged at the upper end and the lower end of the transmission type blood oxygen probe 592, the transmitting tube is arranged on the PCB below, the receiving tube is arranged on the PCB above, and the two PCBs are connected through the cable; the reflective blood oxygen probe 591 is formed by positioning a reflective probe PCB on a transmitting tube and a receiving tube.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are considered to be within the scope of the invention as defined by the following claims.

Claims (10)

1. The utility model provides a wearing formula multi-parameter guardianship equipment which characterized in that: including body temperature probe, body temperature probe has multi-parameter measuring unit through a first cable electric connection, multi-parameter measuring unit has main measuring unit through a second cable electric connection, main measuring unit communication connection has the monitor host computer.

2. The wearable multi-parameter monitoring device of claim 1, wherein: the body temperature probe comprises a metal shell, a heat-conducting resin block arranged in the metal shell and an NTC temperature sensor arranged in the heat-conducting resin block, wherein the NTC temperature sensor and the metal shell are both electrically connected with the multi-parameter measuring unit.

3. The wearable multi-parameter monitoring device of claim 1, wherein: the multi-parameter measuring unit comprises a first shell made of stainless steel and a first control circuit board arranged in the first shell, the first shell is electrically connected with the body temperature probe, the first control circuit board is electrically connected with the main measuring unit, and a signal acquisition module is arranged on the first control circuit board.

4. The wearable multi-parameter monitoring device of claim 3, wherein: the bottom of the first shell is provided with a reflective sensor which is electrically connected with the first control circuit board and is used for measuring the blood oxygen saturation.

5. The wearable multi-parameter monitoring device of claim 3, wherein: first casing bottom is provided with and is used for detecting respiratory first pressure sensor with first control circuit board electric connection or be provided with on the first control circuit board and be used for detecting respiratory acceleration sensor.

6. The wearable multi-parameter monitoring device of claim 1, wherein: the main measuring unit comprises a cuff and a second casing arranged on the cuff, a second control circuit board, an air pump, an electromagnetic valve and a battery are arranged in the second casing, the air pump, the electromagnetic valve and the battery are all electrically connected with the second control circuit board, the air pump is communicated with the cuff in a sealing mode, the electromagnetic valve is arranged between the air pump and the cuff, a cuff pressing block is arranged at the bottom of the second casing, a second pressure sensor is arranged at the bottom of the second control circuit board, and the second pressure sensor is electrically connected with the second control circuit board.

7. The wearable multi-parameter monitoring device of claim 1, wherein: the main measuring unit is in wired communication connection with the monitor host through a third cable, and a socket matched and plugged with a plug connector of the third cable is arranged on the monitor host.

8. The wearable multi-parameter monitoring device of claim 1, wherein: the monitor host is provided with a charging seat, and the main measuring unit is provided with a charging module matched with the charging seat.

9. The wearable multi-parameter monitoring device of claim 1, wherein: the multi-parameter measuring unit comprises an ear clip type blood oxygen probe for detecting blood oxygen saturation and pulse rate, and a breathing measuring unit for detecting breathing, wherein the ear clip type blood oxygen probe and the breathing measuring unit are all electrically connected with the main measuring unit, a transmission type optical sensor electrically connected with the main measuring unit is arranged in the ear clip type blood oxygen probe, the breathing measuring unit comprises a bandage, a breathing detecting probe arranged at one end of the bandage, a plurality of buttonholes are arranged on the bandage, and a bandage buckle matched with the buttonholes is arranged on the breathing detecting probe.

10. The wearable multi-parameter monitoring device of claim 1, wherein: main measuring unit electric connection has ring formula blood oxygen probe, ring formula blood oxygen probe is that cavity indicates annular ring formula blood oxygen probe, ring formula blood oxygen probe is reflective blood oxygen probe or transmissive blood oxygen probe, reflective blood oxygen probe includes reflective casing, sets up the reflective PCB in reflective casing, be provided with reflective transmitting tube, reflective receiving tube on the reflective PCB, transmissive blood oxygen probe includes transmissive casing, sets up first transmissive PCB and the second transmissive PCB in transmissive casing, first transmissive PCB and second transmissive PCB electric connection just set up the upper and lower both ends at transmissive casing relatively, be provided with the transmissive receiving tube on the first transmissive PCB, be provided with the transmissive transmitting tube on the second transmissive PCB.

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