CN219229853U - Sleep monitoring eye-shade - Google Patents

Abstract

The utility model relates to the technical field of sleep monitoring products, in particular to a sleep monitoring eye shield, which aims to solve the problems that the existing sleep monitoring equipment cannot meet the requirement of a user on self monitoring in a home environment, long cables interfere with human sleep and the cables fall off due to the change of the positions of the human bodies. The utility model provides a sleep monitoring eye shield, which comprises an eye shield assembly, a fixing assembly, a first sensor assembly and a second sensor assembly; the eye shield assembly comprises a main frame, wherein a convex arc structure is symmetrically arranged on one side of the main frame, which is close to the nose of a human body, and a groove with an opening facing the nose is formed at the intersection of the two arc structures; the fixing component is connected with the eye shield component and is abutted with the head of the human body, and is used for fixing the eye shield component on eyes and forehead; the first sensor assembly is connected with the main frame; the second sensor assembly is disposed above the forehead of the person, and is connected with the eye shield assembly and electrically connected with the first sensor assembly.

Description

Sleep monitoring eye-shade

Technical Field

The utility model relates to the technical field of sleep monitoring products, in particular to a sleep monitoring eye shield.

Background

Along with the improvement of living standard, people pay more attention to sleep quality. Some people have sleep apnea and hypopnea, which is expressed as recurrent episodes of apnea occurring during each night of sleep, with a frequency of more than 5 times per hour, or more than 30 times during 7 hours of sleep. It is one of the more common sleep related diseases at present, and sleep apnea can cause various harm to the physical health of people.

Currently, polysomnography (PSG) products are available on the market for monitoring, however, PSG detection operation is complex, usually, respiratory devices such as nasal oxygen tubes and the like need to be fixed at the mouth and nose parts of a sleeping person through an adhesive tape, a gyroscope is fixed at the chest position through a binding tape, the devices are connected with a host through a long signal cable, the host is placed beside a bed, the host needs a power line to be connected with a power supply, and signals of the signal line acquisition devices are processed, so that the sleeping state is obtained through analysis. These operations require additional specialized technicians for manual placement and operation, which is time consuming and labor intensive; moreover, the host computer and other devices need to be connected with a plurality of longer signal cables, sleep of a user is disturbed, and actions such as turning over of the user can possibly lead to cable falling off, so that measurement fails.

Therefore, the existing sleep monitoring equipment cannot meet the requirement of users on self-monitoring in a home environment, and meanwhile, long cables interfere with the sleep of the users, and the cables can fall off due to actions such as turning over of the users, so that detection data are inaccurate.

Disclosure of Invention

The utility model aims to provide a sleep monitoring eye shield so as to solve the problems that the existing sleep monitoring equipment cannot meet the requirement of a user on self monitoring in a home environment, long cables interfere with human sleep and the cables fall off due to the change of the positions of the human bodies.

In order to solve the technical problems, the technical scheme provided by the utility model is as follows:

a sleep monitoring eye shield, comprising: an eye shield assembly, a securing assembly, a first sensor assembly, and a second sensor assembly;

the eye cover assembly comprises a main frame, wherein one side of the main frame, which is close to the nose of a human body, is symmetrically provided with a protruding arc structure, a groove with an opening facing the nose is formed at the intersection of the two arc structures, and the groove is abutted with the nose of the human body;

the fixing component is connected with the eye shield component and is abutted with the head of the human body, and the fixing component is used for fixing the eye shield component on eyes and forehead;

the first sensor assembly is connected with the main frame, the first sensor assembly is provided with a first probe and a second probe, the first probe is aligned with nostrils, and the second probe is arranged at the mouth and is used for monitoring breathing conditions;

the second sensor assembly is arranged above the forehead of the human body, connected with the eye shield assembly and electrically connected with the first sensor assembly and used for monitoring and analyzing the influence of sleeping postures of the human body on breathing.

In an alternative embodiment of the present utility model,

the eye shield assembly further includes a first lens portion;

the main frame is provided with a first lens groove along the circumferential direction of the main frame, and the first lens part is inserted into the first lens groove;

the second sensor assembly is coupled to the first lens portion.

In an alternative embodiment of the present utility model,

the eye shield assembly further includes a second lens portion;

the second lens part is arranged above the first lens part and is detachably connected with the main frame.

In an alternative embodiment of the present utility model,

the main frame is provided with a second lens groove along the circumferential direction of the main frame, and the second lens part is inserted into the second lens groove.

In an alternative embodiment of the present utility model,

the fixing component comprises an elastic belt;

the two ends of the elastic band are respectively connected with the two sides of the eye cover component.

In an alternative embodiment of the present utility model,

the eye shield assembly further comprises a nose shield;

the nose wing cover is of an inverted V-shaped structure, protrudes in a direction away from the face and is connected with the groove.

In an alternative embodiment of the present utility model,

the first sensor assembly further includes a housing;

the shell is connected with the nose wing cover, and the first probe and the second probe are connected with the shell.

In an alternative embodiment of the present utility model,

the first sensor assembly further includes a data line for transmitting data;

the data wire is inserted into the shell and is electrically connected with the second sensor assembly, and the first probe and the second probe are electrically connected with the data wire.

In an alternative embodiment of the present utility model,

the second sensor assembly comprises a data acquisition circuit board, an acceleration sensor and a microprocessor;

the data acquisition circuit board is connected with the first lens part;

the acceleration sensor and the microprocessor are both connected to the data acquisition circuit board, the acceleration sensor is electrically connected with the microprocessor, the acceleration sensor is used for detecting sleeping postures of a human body, and the microprocessor is used for analyzing data.

In an alternative embodiment of the present utility model,

the second sensor assembly further comprises a memory, a Bluetooth part and a power supply part;

the memory, the Bluetooth part and the power supply part are all connected to the data acquisition circuit board, and the memory and the Bluetooth part are all electrically connected with the microprocessor;

the memory is used for storing data, and the Bluetooth part is used for communicating with external equipment.

In summary, the technical effects achieved by the utility model are as follows:

the utility model provides a sleep monitoring eye shield, comprising: an eye shield assembly, a securing assembly, a first sensor assembly, and a second sensor assembly; the eye cover assembly comprises a main frame, wherein one side of the main frame, which is close to the nose of a human body, is symmetrically provided with a convex arc structure, a groove with an opening facing the nose is formed at the intersection of the two arc structures, and the groove is abutted with the nose of the human body; the fixing component is connected with the eye shield component and is abutted with the head of the human body, and is used for fixing the eye shield component on eyes and forehead; the first sensor assembly is connected with the main frame, and is provided with a first probe and a second probe, the first probe is aligned with nostrils, and the second probe is arranged at the mouth part and is used for monitoring breathing conditions; the second sensor component is arranged above the forehead of the human body, connected with the eye cover component and electrically connected with the first sensor component and used for monitoring and analyzing the influence of sleeping postures of the human body on breathing.

The eyeshade assembly is used as a carrier, the eyeshade assembly is fixed to the eyes and forehead through the fixing assembly, the first sensor assembly is connected with the main frame, the first probe is aligned with nostrils, the second probe is aligned with the mouth, the second sensor assembly is connected with the eyeshade assembly, the sleeping posture of a human body can be detected through being arranged above the forehead, the eyeshade assembly is electrically connected with the first sensor assembly, and comprehensive analysis is carried out on breathing and sleeping posture data, the eyeshade is used, no professional operation is needed, no special field is needed to be arranged, meanwhile, the eyeshade assembly and each sensor assembly are fixed above the face, long cables are not needed to be arranged, the relative positions of all parts are not influenced by the human body turning over, and the problems that the existing sleeping monitoring equipment cannot meet the requirement of users for self monitoring in a family environment, and the long cables interfere with human body sleeping and lead to cable falling are solved.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are needed in the description of the embodiments or the prior art will be briefly described, and it is obvious that the drawings in the description below are some embodiments of the present utility model, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a sleep monitoring eye mask according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of another embodiment of a sleep monitoring eye mask according to an embodiment of the present utility model.

Icon: 100-an eye shield assembly; 110-a main frame; 111-arc structure; 112-grooves; 120-a first lens portion; 130-a nose mask; 140-supporting an adjusting part; 200-fixing the assembly; 210-elastic band; 211-a first belt; 212-a second belt; 220-a snap; 300-a first sensor assembly; 310-a first probe; 320-a second probe; 330-a housing; 400-a second sensor assembly; 410-a data acquisition circuit board; 420-an acceleration sensor; 430-a microprocessor; 440-memory; 450-bluetooth department; 460-a power supply section; 500-a first piezoelectric sensor; 600-a second piezoelectric sensor; 700-a third piezoelectric sensor; 800-a first vibration sensor; 900-a second vibration sensor; 1000-a third vibration sensor; 1100-buzzer.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. The components of the embodiments of the present utility model generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Some embodiments of the present utility model are described in detail below with reference to the accompanying drawings. The following embodiments and features of the embodiments may be combined with each other without conflict.

The existing sleep monitoring equipment cannot meet the requirement that a user monitors in a home environment by himself, meanwhile, long cables interfere with the sleep of the user, and the cables fall off due to actions such as turning over of the user, so that detection data are inaccurate.

In view of this, the present utility model provides a sleep monitoring eye mask comprising: the eye shield assembly 100, the fixation assembly 200, the first sensor assembly 300, and the second sensor assembly 400; the eye mask assembly 100 comprises a main frame 110, wherein a convex arc-shaped structure 111 is symmetrically arranged on one side of the main frame 110 close to the nose of a human body, a groove 112 with an opening towards the nose is formed at the intersection of the two arc-shaped structures 111, and the groove 112 is abutted with the nose of the human body; the fixing component 200 is connected with the eye shield component 100, and the fixing component 200 is abutted with the head of the human body and is used for fixing the eye shield component 100 on eyes and forehead; the first sensor assembly 300 is connected with the main frame 110, the first sensor assembly 300 is provided with a first probe 310 and a second probe 320, the first probe 310 is aligned with nostrils, and the second probe 320 is arranged at the mouth part and is used for monitoring breathing conditions; the second sensor assembly 400 is disposed over the forehead of the human body, is connected to the eye mask assembly 100, and is electrically connected to the first sensor assembly 300 for monitoring and analyzing the influence of the sleeping posture of the human body on the respiration.

The eye shield assembly 100 is used as a carrier, the eye shield assembly 100 is fixed to eyes and forehead parts through the fixing assembly 200, the first sensor assembly 300 is connected with the main frame 110, the first probe 310 is aligned with nostrils, the second probe 320 is aligned with the mouth, the second sensor assembly 400 is connected with the eye shield assembly 100, the sleeping posture of a human body can be detected through being arranged above the forehead, the eye shield assembly 100 is electrically connected with the first sensor assembly 300, and comprehensive analysis is carried out on breathing and sleeping posture data, no professional person is required to operate the eye shield, no special place is required to be arranged, meanwhile, the eye shield assembly 100 and each sensor assembly are fixed above the face, long cables are not required to be arranged, the relative positions of all parts are not influenced by turning over of the human body, and the problems that the existing sleeping monitoring equipment cannot meet the requirement of a user in a home environment, the long cables interfere with sleeping of the human body and the position change of the human body causes the cable to fall off are solved.

Regarding the shape and structure of the eye shield assembly 100, in detail:

as shown in fig. 1, the eye mask assembly 100 includes a main frame 110, a protruding arc structure 111 is symmetrically disposed on one side of the main frame 110 near the nose of the human body, a groove 112 opening toward the nose is formed at the intersection of the two arc structures 111, and the groove 112 abuts against the nose of the human body.

In an alternative embodiment, the eye shield assembly 100 further includes a first lens portion 120; the main frame 110 is provided with a first lens groove along the circumferential direction, and the first lens part 120 is inserted into the first lens groove; the second sensor assembly 400 is connected to the first lens portion 120.

Specifically, the two concave eye sockets are disposed at positions corresponding to two eyes on one side of the main frame 110, where the face is attached, and the first lens portion 120 includes a three-layer structure, including a first layer for attaching the face, a second layer for qualitative feature, and a third layer for shielding light from the face.

In an alternative embodiment, the eye shield assembly 100 further includes a second lens portion; the second lens portion is disposed above the first lens portion 120 and is detachably connected to the main frame 110.

In an alternative embodiment, the main frame 110 is provided with a second lens groove along its circumferential direction, and the second lens portion is inserted into the second lens groove.

Specifically, the second sensor assembly 400 is fixed on the first lens portion 120, and the second lens portion is located above the first lens portion 120, and may be configured as a PC anti-fog lens or a light-shielding lens, and may cover the first lens portion 120, so as to protect the first lens portion 120 and the second sensor assembly 400, such as blocking contaminants such as dust and water from damaging the second sensor assembly 400, so as to ensure accuracy of measurement data. The eye shield assembly 100 is secured to the binocular region by the securing assembly 200 to perform binocular shading functions, as well as device carrier and securing functions.

Regarding the shape and structure of the fixing assembly 200, in detail:

the fixing component 200 is connected with the eye mask component 100, and the fixing component 200 is abutted with the head of the human body and is used for fixing the eye mask component 100 to eyes and forehead.

In an alternative embodiment, the securing assembly 200 includes an elastic band 210; the elastic band 210 has both ends connected to both sides of the eye mask assembly 100, respectively.

Specifically, as the first embodiment, one end of the elastic band 210 is connected to one side of the main frame 110, the other end of the elastic band 210 is connected to the other side of the main frame 110, and the main frame 110 is fixed to the face by the elastic force of the elastic band 210, preferably, on the basis of the first embodiment, the outer walls of the two sides of the main frame 110 are connected to the loop-shaped buckles, the two ends of the elastic band 210 extend into the loop-shaped buckles respectively and are clamped in the loop-shaped buckles, and the length of the elastic band 210 can be adjusted in the loop-shaped buckles. As a second embodiment, the elastic band 210 includes a first band 211 and a second band 212 symmetrically disposed at both sides of the main frame 110, and the first band 211 and the second band 212 are connected by a velcro adhesive, so that wearing and taking off of the eye mask are facilitated. As a third embodiment, as shown in fig. 1, the fixing assembly 200 further includes a fastening portion 220, the fastening portion 220 connects the elastic band 210 into a continuous band, specifically, the fastening portion 220 includes a socket buckle and a chuck, the elastic band 210 includes a first band 211 and a second band 212, one end of the first band 211 is connected with the main frame 110, the other end is connected with the socket buckle, one end of the second band 212 is connected with the main frame 110, the other end is connected with the chuck, the chuck is inserted into the socket buckle, and the setting of the fastening portion 220 makes it more convenient to wear the eye mask.

Regarding the shape and structure of the first sensor assembly 300, in detail:

the first sensor assembly 300 is connected to the main frame 110, the first sensor assembly 300 is provided with a first probe 310 and a second probe 320, the first probe 310 is arranged in alignment with the nostril, and the second probe 320 is arranged at the mouth for monitoring the breathing situation.

In an alternative embodiment, as shown in fig. 2, the eye mask assembly further includes a nose-wing mask 130, where the nose-wing mask 130 is configured in an inverted V-shape and protrudes in a direction away from the face, the nose-wing mask 130 is disposed at the groove 112, the nose-wing mask 130 abuts against the nose, and the nose-wing mask 130 is integrally formed with the main frame.

Preferably, in order to adapt to the nose of the human body, a supporting and adjusting part 140 is disposed in the nose-wing cover 130, the supporting and adjusting part 140 is connected between the second layer and the third layer of the first lens part 120, the supporting and adjusting part 140 is made of metal plastic material, and the positioning of the nose-wing cover 130 can be assisted by pressing the shape of the supporting and adjusting part 140, so that the nose-wing cover 130 is tightly attached to the nose bridge of the user.

In an alternative embodiment, the first sensor assembly 300 further includes a housing 330; the housing 330 is connected to the nose mask 130, and the first probe 310 and the second probe 320 are connected to the housing 330.

In an alternative embodiment, the first sensor assembly 300 further includes a data line for transmitting data; the data line is inserted into the housing 330 and electrically connected to the second sensor assembly 400, and the first probe 310 and the second probe 320 are electrically connected to the data line.

Specifically, the first sensor assembly 300 is a heat-sensitive oral-nasal airflow sensor, two first probes 310 are arranged, the first probes 310 and the second probes 320 are heat-sensitive elements, the shell 330 is connected to the groove 112, the groove 112 is convenient for positioning and fixing the probes, the shell 330 can be a universal tube, namely a tube which can be shaped by bending, a data line inside the tube is connected with the data acquisition circuit board 410, data are transmitted to the microprocessor 430 on the data acquisition circuit board 410, the two first probes 310 are respectively placed at nostrils at two sides by adjusting the universal tube, the second probes 320 are aligned to the mouth, in the breathing process of a human body, the heat-sensitive elements generate signals in proportion to temperature changes between expiration and inspiration, and the signals have the same fluctuation with the breathing frequency; if there is no change in the temperature of the gas when the person is apnoea, the output signal will not fluctuate, and the data acquisition circuit board 410 and the microprocessor 430 can calculate the breathing frequency or whether there is breathing through signal processing and calculation, so that it can be judged whether the dangerous condition of apnoea or abnormal breathing frequency occurs, further, whether the nasal obstruction condition occurs or not can be monitored through the first probe 310 and the second probe 320, and only the breathing condition is detected. Further, the thermosensitive oronasal airflow sensor is arranged above the face and between the oronasal and eyes, and is connected with the data acquisition circuit board 410 through a cable, the cable reaches the data acquisition circuit board 410 in the middle of the eye cover from the sensor probe of the oronasal part, so that the operation is simple and convenient, and the user can operate the thermosensitive oronasal airflow sensor by only adjusting the positions of the elastic band and the thermosensitive oronasal airflow sensor probe without influencing the normal sleeping of the user.

As another alternative embodiment, the housing 330 may be configured as a frame structure for supporting the probe, and the housing 330 may be configured as a universal tube, i.e. a tube that can be bent and shaped, and the positions of the first probe 310 and the second probe 320 may be adjusted according to the actual situation. The heat sensitive oral nasal airflow sensor is electrically connected to the microprocessor 430 and transmits data to the microprocessor 430 via bluetooth. Such an embodiment may not provide a data line for transmitting data via bluetooth.

Regarding the shape and structure of the second sensor assembly 400, in detail:

the second sensor assembly 400 is disposed over the forehead of the human body, is connected to the eye mask assembly 100, and is electrically connected to the first sensor assembly 300 for monitoring and analyzing the influence of the sleeping posture of the human body on the respiration.

In an alternative embodiment, the second sensor assembly 400 includes a data acquisition circuit board 410, an acceleration sensor 420, a microprocessor 430; the data acquisition circuit board 410 is connected with the first lens portion 120; the acceleration sensor 420 and the microprocessor 430 are both connected to the data acquisition circuit board 410, the acceleration sensor 420 is electrically connected to the microprocessor 430, the acceleration sensor 420 is used for detecting the sleeping gesture of the human body, and the microprocessor 430 is used for analyzing data.

In an alternative embodiment, the second sensor assembly 400 further includes a memory 440, a bluetooth portion 450, and a power supply portion 460; the memory 440, the bluetooth portion 450 and the power supply portion 460 are all connected to the data acquisition circuit board 410, and the memory 440 and the bluetooth portion 450 are all electrically connected to the microprocessor 430; the memory 440 is used to store data, and the bluetooth section 450 is used to communicate with external devices.

Specifically, the data acquisition circuit board 410 is fixed on the first lens portion 120, after the eye mask is worn, the data acquisition circuit board 410 is located above the forehead portion of the human body, the acceleration sensor 420, the microprocessor 430, the memory 440, the bluetooth portion 450 and the power supply portion 460 are mounted on the data acquisition circuit board 410, the microprocessor 430 performs data acquisition, analysis and storage of the sensor, the microprocessor 430 is electrically connected with the bluetooth portion 450, and performs data transmission with an external intelligent terminal through the bluetooth portion 450; the acceleration sensor 420 is a triaxial acceleration sensor, and is integrated on the data acquisition circuit board 410, because the eyeshade is bound and positioned above the forehead of the human body, and along with the movement of the head and the eyeshade, the sleeping postures of the user, including left lateral lying, right lateral lying and lying, can be detected, and the data acquisition circuit board 410 and the microprocessor 430 can measure the corresponding relation between the sleeping postures and the breathing state by combining the sleeping postures and the breathing frequency, so that the user can be reminded of which sleeping postures have adverse effects on breathing; the memory 440 is a nonvolatile memory 440, and is used for storing collected data, and can still store data under the condition of power failure, and the stored data can be used for later data analysis, so as to completely analyze the sleeping condition of the user in the whole night; the bluetooth part 450 is used for communicating with an external intelligent terminal, uploading the acquired data stored in the memory 440 to a mobile phone or a computer through a bluetooth communication technology, and analyzing all sleeping conditions of a user through processing software of the computer or the mobile phone; the acceleration sensor 420, the microprocessor 430, the memory 440, the bluetooth portion 450, and the power supply portion 460 are all electrically connected with the data acquisition circuit board 410, and the power supply portion 460 is used for providing working power for each monitoring module such as the data acquisition circuit board 410, so as to realize charge and discharge management of the battery.

In an alternative embodiment, to ensure that the eye mask is worn in the correct position, the present embodiment is further provided with a first piezoelectric sensor 500, a second piezoelectric sensor 600, and a third piezoelectric sensor 700. The first piezoelectric sensor 500 is disposed on the back surface of the data acquisition circuit board 410 and is attached to the first layer of the first lens portion 120; the second piezoelectric sensor 600 and the third piezoelectric sensor 700 are respectively connected to the left side and the right side of the nose mask 130, and are arranged near the groove 112 to be attached to a layer of the nose mask 130 contacting the nose; the first piezoelectric sensor 500, the second piezoelectric sensor 600, and the third piezoelectric sensor 700 are connected through the signal line data acquisition circuit board 410. When the eye patch is worn to the correct position, the nose wing cover 130 is completely attached to the nose wing of the human body, the three piezoelectric sensors can detect the pressure, the position of the eye patch can be judged to be correct only if the data detected by the three piezoelectric sensors exceeds a certain threshold value, the elastic band is firmly fixed, the nose wing cover 130 is completely attached to the nose wing of the human body, and then the positions of the first probe 310, the second probe 320 and the acceleration sensor 420 can be deduced to be correct, so that the data acquired by the sensors are reliable. If at least one of the three piezoelectric sensor data does not reach a certain threshold value, it is determined that the position of the eye mask is shifted during sleep, and it is further inferred that the positions of the first probe 310, the second probe 320 and the acceleration sensor 420 are also shifted, so that the measured data has no reference meaning, and abnormal data can be identified for the data.

In an alternative embodiment, in order to indicate to the user that the wearing position of the eye mask is incorrect, the present embodiment further provides a first vibration sensor 800, where the first vibration sensor 800 is connected to the back surface of the data acquisition circuit board 410 and is attached to the first layer of the first lens portion 120, and when the pressure value detected by the first piezoelectric sensor 500 does not reach the set threshold value, the first vibration sensor 800 performs adhesion of the middle portion of the vibration-indicating eye mask to be not tight enough, the user senses the indication through skin contact, and then performs adjustment of the eye mask position and the elastic band.

In an alternative embodiment, the present embodiment further provides a second vibration sensor 900 and a third vibration sensor 1000, which are respectively connected to the left and right sides of the nose mask 130, and are attached to a layer of the nose mask 130 that contacts the nose, and are connected to the data acquisition circuit board 410 through signal lines. When one or both of the second piezoelectric sensor 600 or the third piezoelectric sensor 700 detects that the pressure does not reach the set threshold, the vibration sensor corresponding to one side or both sides vibrates, and the one side or both sides of the tip of the nose are not close enough to the bridge of the nose, the user feels the tip through skin contact, and then presses the support adjustment part 140, so that the tip cover 130 is close to the nose of the face. Further, by providing the nose mask 130, the support adjustment portion 140, the second piezoelectric sensor 600, the third piezoelectric sensor 700, the second vibration sensor 900, and the third vibration sensor 1000, positioning of the thermosensitive oronasal airflow sensor probe is assisted together, thereby realizing accurate measurement.

In an alternative implementation manner, the embodiment further includes a buzzer 1100, different sound effects are designed, a prompt tone is emitted when the sensors on the data acquisition circuit board 410 start working, each piezoelectric sensor emits a prompt tone after detecting that the wearing position of the eyeshade is correct, each piezoelectric sensor emits a prompt tone after detecting that the wearing position of the eyeshade is shifted, and further, the vibration prompt of each vibration sensor is combined to indicate which position of the eyeshade is shifted.

The embodiment uses the eye cover assembly 100 as a carrier, the data acquisition circuit board 410, the piezoelectric sensor, the vibration sensor and the like form an intelligent monitoring module, the intelligent monitoring module is embedded in the eye cover assembly 100, the intelligent monitoring module adopts a design of miniaturization and micro-power consumption, the eye cover assembly can continuously work for more than 10 hours through the power supply of a rechargeable battery, the eye cover assembly can work in a sleeping period of a user every night, long-term power supply is realized without using an extra power line, and the operation is simpler and more convenient.

The sleep monitoring eye shade that this embodiment provided has intelligent monitoring function, but monitoring sleep apnea low ventilation state, not only has traditional eye shade and shelters from the effect of light, assists people's sleep, because it binds to the both eyes position through the elastic cord moreover, combines the positioning of the nose wing cover 130 and the support adjustment portion 140 at nose wing position, has played carrier and fixed, the effect of location, has realized the fixed carrier of the data acquisition circuit board 410 and each sensor of intelligent monitoring module. Further, by the piezoelectric sensors and vibration sensors provided at the middle part of the eyecup and at both sides of the nose wing cover 130, it is possible to sense whether the eyecup position is shifted, thereby further judging whether the data measured during sleep is valid. The eyeshade is used as a carrier to assist in positioning of the thermosensitive oronasal airflow sensor probe, so that communication cables among the modules are shortened. Because the eyeshade, each sensor and the connecting cable are all fixed above the face, the relative position of each module is not influenced by the turning of a human body, and the problems that the sensor cable falls off due to position change and the longer cable interferes with normal sleeping of a person are solved.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model, and not for limiting the same; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some or all of the technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit of the utility model.

Claims (10)

1. A sleep monitoring eye shield, comprising: an eye shield assembly (100), a securing assembly (200), a first sensor assembly (300), and a second sensor assembly (400);

the eye cover assembly (100) comprises a main frame (110), wherein a protruding arc-shaped structure (111) is symmetrically arranged on one side, close to the nose of a human body, of the main frame (110), a groove (112) with an opening towards the nose is formed at the intersection of the two arc-shaped structures (111), and the groove (112) is abutted with the nose of the human body;

the fixing component (200) is connected with the eye shield component (100), and the fixing component (200) is abutted with the head of a human body and is used for fixing the eye shield component (100) to eyes and forehead;

the first sensor assembly (300) is connected with the main frame (110), the first sensor assembly (300) is provided with a first probe (310) and a second probe (320), the first probe (310) is aligned with nostrils, and the second probe (320) is arranged at the mouth and is used for monitoring breathing conditions;

the second sensor assembly (400) is arranged above the forehead of the human body, is connected with the eye shield assembly (100) and is electrically connected with the first sensor assembly (300) and is used for monitoring and analyzing the influence of sleeping posture of the human body on breathing.

2. The sleep monitoring eye mask of claim 1, wherein the eye mask comprises a plurality of eye-masks,

the eye shield assembly (100) further includes a first lens portion (120);

the main frame (110) is provided with a first lens groove along the circumferential direction of the main frame, and the first lens part (120) is inserted into the first lens groove;

the second sensor assembly (400) is connected to the first lens portion (120).

3. The sleep monitoring eye mask of claim 2, wherein,

the eye shield assembly (100) further includes a second lens portion;

the second lens part is arranged above the first lens part (120) and is detachably connected with the main frame (110).

4. The sleep monitoring eye mask of claim 3, wherein,

the main frame (110) is provided with a second lens groove along the circumferential direction, and the second lens part is inserted into the second lens groove.

5. The sleep monitoring eye mask of claim 1, wherein the eye mask comprises a plurality of eye-masks,

the securing assembly (200) includes an elastic band (210);

the two ends of the elastic band (210) are respectively connected with the two sides of the eye cover assembly (100).

6. The sleep monitoring eye mask of claim 1, wherein the eye mask comprises a plurality of eye-masks,

the eye shield assembly (100) further includes a nose shield (130);

the nose wing cover (130) is arranged in an inverted V-shaped structure, protrudes in a direction away from the face and is connected with the groove (112).

7. The sleep monitoring eye mask of claim 6, wherein,

the first sensor assembly (300) further comprises a housing (330);

the shell (330) is connected with the nose wing cover (130), and the first probe (310) and the second probe (320) are connected with the shell (330).

8. The sleep monitoring eye mask of claim 7, wherein the eye mask comprises,

the first sensor assembly (300) further comprises a data line for transmitting data;

the data line is inserted into the shell (330) and is electrically connected with the second sensor assembly (400), and the first probe (310) and the second probe (320) are electrically connected with the data line.

9. The sleep monitoring eye mask of claim 2, wherein,

the second sensor assembly (400) comprises a data acquisition circuit board (410), an acceleration sensor (420) and a microprocessor (430);

the data acquisition circuit board (410) is connected with the first lens part (120);

the acceleration sensor (420) and the microprocessor (430) are both connected to the data acquisition circuit board (410), the acceleration sensor (420) is electrically connected with the microprocessor (430), the acceleration sensor (420) is used for detecting sleeping postures of a human body, and the microprocessor (430) is used for analyzing data.

10. The sleep monitoring eye mask of claim 9, wherein the eye mask comprises,

the second sensor assembly (400) further comprises a memory (440), a bluetooth portion (450) and a power supply portion (460);

the memory (440), the Bluetooth part (450) and the power supply part (460) are all connected to the data acquisition circuit board (410), and the memory (440) and the Bluetooth part (450) are all electrically connected with the microprocessor (430);

the memory (440) is used for storing data, and the Bluetooth part (450) is used for communicating with an external device.

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