CN219423129U - Sleep auxiliary eye-shade - Google Patents

Abstract

The utility model relates to the technical field of sleep assisting equipment, and particularly discloses a sleep assisting eye shield. The heart rate blood oxygen monitoring module, the body movement signal monitoring module, the music module, the heating module and the light module are arranged on the shading eye cover worn by assisting sleeping, the heart rate blood oxygen monitoring module and the body movement signal monitoring module are used for acquiring heart rate and blood oxygen data before sleeping of a user and judging the state of the user at the moment, the music module, the heating module and the light module are further intelligently controlled according to the state, and the music, eyeball hot compress and light are three sleeping assisting means which are relatively effective at present. The sleep assisting eyeshade is not limited in use environment, one person can cover the eyeshade, excessive manual operation of a user is not needed, and the sleeping assisting eyeshade is small in size and convenient to carry.

Description

Sleep auxiliary eye-shade

Technical Field

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

Background

With the acceleration of urban life rhythm and the rapid increase of life pressure and days, more and more office workers have difficulty in correctly balancing working and resting time, and human body biological clocks are destroyed, so that the sleeping quality at night is reduced, and further, the sleeping quality is further reduced, and the normal working and life quality in the next day are directly influenced.

Conventional methods of aiding sleep generally improve sleep by stimulating brain waves with drugs or by electronic means. For some non-pathological insomnia patients caused by great living pressure or bad living habit, the sleeping difficulty is often temporary and the insomnia degree is light, and the patients only need to be simply helped to enter a sleeping state, so that the patients can self-regulate and relieve symptoms. In this case, if the sleep is assisted by taking the medicine, the sleep-assisting effect will be more obvious, but the patient is liable to depend on the medicine due to the medicine taking, which is unfavorable for the physical and mental health of the patient.

At present, more and more electronic instruments are used for helping sleep, such as a sleep-aiding instrument with the application number of 201910251127.3, the sleep-aiding instrument is specifically a breathing lamp, the period of turning on and off the breathing lamp can be adjusted according to the breathing frequency of a user, music can be played, and acousto-optic integration is achieved. However, the sleep assisting instrument has limited application environment, and only the lamplight can play the sleep assisting effect under the condition that the room is dark, and if the room is shared by other people, the sleep assisting instrument is easy to cause trouble to other people. And the breathing lamp needs more places where the user manually sets up, and is not convenient enough to use.

Disclosure of Invention

The utility model provides a sleep auxiliary eye shield, which solves the technical problems that: the existing sleep aiding instrument such as a sleep aiding breathing lamp is limited in use environment and complex in operation.

In order to solve the technical problems, the utility model provides a sleep auxiliary eye shield, which comprises a main control module, and a heart rate blood oxygen monitoring module, a body movement signal monitoring module, a music module, a heating module and a light module which are connected with the main control module;

the heart rate and blood oxygen monitoring module is used for collecting heart rate and blood oxygen data of a user and sending the data to the main control module;

the body movement signal monitoring module is used for monitoring body movement signals of a user and sending the body movement signals to the main control module;

the main control module is used for controlling the music module, the heating module and the light module according to the heart rate and blood oxygen data and the body movement signal;

the music module is used for playing sleep-aiding music under the control of the main control module;

the heating module is used for heating under the control of the main control module so as to compress eyes of the user;

the light module is used for starting light under the control of the main control module so as to irradiate eyes of the user.

Preferably, the heart rate blood oxygen monitoring module adopts a MAX30102 blood oxygen and heart rate monitoring module.

Preferably, the body movement signal monitoring module adopts an MPU-6050 module.

Preferably, the music module comprises a music master control circuit, an SD card storage module and a power amplifier module, wherein the SD card storage module and the power amplifier module are connected with the music master control circuit;

the music master control circuit adopts NUC505DS13Y as a master control chip;

the SD card storage module is used for storing the sleep-aiding music;

under the control of the main control module, the music main control circuit reads the sleep-aiding music and plays the sleep-aiding music through the power amplification module.

Preferably, the heating module comprises a heating circuit and a temperature sensing circuit, wherein the heating circuit is provided with a heating element, and the heating element is connected with a self-recovery fuse;

the temperature sensing circuit measures the temperature of the heating element through the thermistor and feeds back the temperature to the main control module, and the main control module adjusts the heating circuit according to the fed-back temperature, so that constant-temperature closed-loop control of the heating element is realized.

Preferably, the light module is provided with lamp groups of more than two colors.

Preferably, the sleep assisting eye cover further comprises an SPI-FLASH data storage module connected with the main control module, and the SPI-FLASH data storage module is used for providing data storage service for the main control module.

Preferably, the sleep assisting eye mask further comprises a wireless data transmission module connected with the main control module, wherein the wireless data transmission module is used for being wirelessly connected with the terminal selected by the user so as to transmit data sent by the main control module to the terminal.

Preferably, the sleep-assisting eye mask further comprises a power supply module;

the power module comprises a magnetic charging circuit, a 5V boosting and discharging circuit, a 3.3V LDO voltage reducing circuit and a battery electric quantity monitoring circuit;

the magnetic charging circuit is used for charging the storage battery;

the 5V boosting discharge circuit is used for boosting the discharge voltage of the storage battery so as to output 5V voltage for supplying power to components needing 5V voltage power supply;

the 3.3V LDO step-down circuit (93) is used for step-down the 5V voltage to output 3.3V voltage for supplying power to components needing 3.3V voltage power supply;

the battery electric quantity monitoring circuit is used for monitoring the electric quantity of the storage battery and feeding back the electric quantity to the main control module.

Preferably, the sleep assisting eye shield further comprises a key module connected with the main control module, and the key module is used for realizing the functions of a power switch and the function switching.

The heart rate blood oxygen monitoring module, the body movement signal monitoring module, the music module, the heating module and the light module are arranged on the shading eye cover worn by assisting sleeping, the heart rate blood oxygen monitoring module and the body movement signal monitoring module are used for acquiring heart rate and blood oxygen data before sleeping of a user and body movement signals so as to judge the state of the user at the moment, the music module, the heating module and the light module are further intelligently controlled according to the state, and the music, eyeball hot compress and light are three effective sleeping assisting means at present. The sleep assisting eyeshade is not limited in use environment, one person can cover the eyeshade, excessive manual operation of a user is not needed, and the sleeping assisting eyeshade is small in size and convenient to carry.

Drawings

Fig. 1 is a block diagram of a sleep-assisting eye mask according to an embodiment of the present utility model;

FIG. 2 is a circuit diagram of a heart rate blood oxygen monitoring module provided by an embodiment of the present utility model;

fig. 3 is a circuit diagram of a body motion signal monitoring module according to an embodiment of the present utility model;

fig. 4-1 is a circuit diagram of a music master circuit according to an embodiment of the present utility model;

FIG. 4-2 is a circuit diagram of an SD card memory module according to an embodiment of the present utility model;

fig. 4-3 are circuit diagrams of a power amplifier module according to an embodiment of the present utility model;

FIG. 5 is a circuit diagram of a heating module provided by an embodiment of the present utility model;

fig. 6 is a circuit diagram of a light module according to an embodiment of the present utility model;

FIG. 7 is a circuit diagram of an SPI-FLASH data storage module provided by an embodiment of the present utility model;

fig. 8 is a circuit diagram of a wireless data transmission module according to an embodiment of the present utility model;

FIG. 9-1 is a circuit diagram of a magnetically attractable charging circuit provided by an embodiment of the present utility model;

FIG. 9-2 is a circuit diagram of a 5V boost discharge circuit provided by an embodiment of the present utility model;

fig. 9-3 are circuit diagrams of a 3.3V LDO step-down circuit provided by an embodiment of the present utility model;

fig. 9-4 are circuit diagrams of a battery power monitoring circuit provided by an embodiment of the present utility model;

FIG. 10 is a circuit diagram of a key module according to an embodiment of the present utility model;

fig. 11 is a circuit diagram of a master control module according to an embodiment of the present utility model.

Reference numerals: the device comprises a main control module 1, a heart rate blood oxygen monitoring module 2, a body movement signal monitoring module 3, a music module 4, a music main control circuit 41, an SD card storage module 42, a power amplifier module 43, a heating module 5, a heating circuit 51, a temperature sensing circuit 52, a light module 6, an SPI-FLASH data storage module 7, a wireless data transmission module 8, a power supply module 9, a magnetic charging circuit 91,5V, a boosting and discharging circuit 92, a 3.3V LDO voltage reducing circuit 93, a battery power monitoring circuit 94 and a key module 10.

Detailed Description

The following examples are given for the purpose of illustration only and are not to be construed as limiting the utility model, including the drawings for reference and description only, and are not to be construed as limiting the scope of the utility model as many variations thereof are possible without departing from the spirit and scope of the utility model.

The embodiment of the utility model provides a sleep assisting eye mask, which comprises a main control module 1, a heart rate blood oxygen monitoring module 2, a body movement signal monitoring module 3, a music module 4, a heating module 5, a light module 6, an SPI-FLASH data storage module 7, a wireless data transmission module 8, a power supply module 9 and a key module 10 connected with the main control module 1, wherein the main control module 1 is connected with the heart rate blood oxygen monitoring module 2.

The heart rate and blood oxygen monitoring module 2 is used for collecting heart rate and blood oxygen data of a user and sending the data to the main control module 1. The body movement signal monitoring module 3 is used for and sends to the main control module 1. The main control module 1 is used for controlling the music module 4, the heating module 5 and the light module 6 according to heart rate and blood oxygen data and body movement signals.

The music module 4 is used for playing sleep-aiding music under the control of the main control module 1.

The heating module 5 is used for heating under the control of the main control module 1 so as to compress eyes of a user.

The light module 6 is used for starting light under the control of the main control module 1 so as to irradiate eyes of a user.

In this embodiment, the main control module 1 determines the body movement amplitude and the body movement frequency of the user after wearing the eye mask according to the body movement signal, and determines the sleeping state of the user by combining the heart rate and blood oxygen data of the user. In order to enable the user to form a habit of falling asleep independently, the main control module 1 does not take any operation on the music module 4, the heating module 5 and the light module 6 within ten minutes after being started (default is ten minutes, the user can set the main control module by himself), and if the user does not fall asleep successfully after ten minutes, corresponding sleep-aiding operation is taken according to the sleeping state of the user at the moment.

If the user is in a slightly difficult state of falling asleep at this time, one of the music module 4, the heating module 5 and the light module 6 is started, if the user does not fall asleep successfully or has obvious signs of falling asleep after five minutes, the user is switched to the other one of the music module 4, the heating module 5 and the light module 6 (if the user does not fall asleep successfully or has obvious signs of falling asleep after five minutes, the corresponding module is closed after five minutes, the module is recorded at this time, the user is started preferentially after five minutes, and the user is in a moderately difficult state of falling asleep if the user does not fall asleep successfully or has obvious signs of falling asleep after five minutes).

If the user is in a moderate difficulty state of falling asleep at this time, two of the music module 4, the heating module 5 and the light module 6 are started, if the user does not fall asleep successfully or has obvious signs of falling asleep after five minutes, the user is switched to the other two of the music module 4, the heating module 5 and the light module 6 (if the user does not fall asleep successfully or has obvious signs of falling asleep after five minutes, the corresponding module is closed, the user is already in a severe difficulty state of falling asleep after five minutes, if the user does not fall asleep successfully or has obvious signs of falling asleep after five minutes, the corresponding module is closed after five minutes, the module is recorded, the user is started before the user falls asleep after five minutes, and the user is in a severe difficulty state of falling asleep after five minutes.

If the user is in a severe sleep difficulty state at this time, the music module 4, the heating module 5 and the light module 6 are simultaneously started, and the corresponding modules are closed after the user falls asleep successfully.

The above control procedure is only one example, and various embodiments are also possible.

Fig. 2 is a circuit diagram of a heart rate blood oxygen monitoring module 2, and the heart rate blood oxygen monitoring module 2 adopts a MAX30102 blood oxygen and heart rate monitoring module. The MAX30102 heart rate blood oxygen chip and a microcontroller integrating heart rate blood oxygen algorithm can directly output heart rate blood oxygen values. The integrated level is high, the power consumption is low, and the volume is small.

Fig. 3 is a circuit diagram of the body movement signal monitoring module 3, and the body movement signal monitoring module 3 adopts an MPU-6050 module. MPU-6050 integrates a 3-axis MEMS gyroscope, a 3-axis MEMS accelerometer, and a scalable digital motion processor DMP. The whole range of the angular velocity sensing range of MPU-6000 (6050) is + -250, + -500, + -1000 and + -2000 DEG/sec (dps), and the fast and slow actions can be accurately tracked.

The music module 4 includes a music master control circuit 41, an SD card memory module 42 and a power amplifier module 43 connected to the music master control circuit 41. Fig. 4-1, 4-2, and 4-3 are circuit diagrams of the music master control circuit 41, the SD card memory module 42, and the power amplifier module 43, respectively.

The music master circuit 41 adopts NUC505DS13Y as a master chip.

The SD card storage module 42 is used for storing sleep-aiding music. The SD card can be taken out, and the user can store sleep-aiding music according to own preference.

Under the control of the main control module 1, the music main control circuit 41 reads sleep-aiding music and plays the sleep-aiding music through the power amplification module 43.

It should be noted that the power amplifier module 43 may be converted into an earphone module, and may be applied to a scene unsuitable for playing music.

As shown in fig. 5, the heating module 5 includes a heating circuit 51 and a temperature sensing circuit 52. It can be seen that the heating circuit 51 is provided with a heating element to which a self-healing fuse is connected. The temperature sensing circuit 52 measures the temperature of the heating element through the thermistor and feeds back the temperature to the main control module 1, and the main control module 1 adjusts the heating circuit 51 according to the fed-back temperature, so that constant-temperature closed-loop control of the heating element is realized.

The light module 6 is provided with lamp groups of more than two colors. The circuit diagram of the light module 6 of this example is shown in fig. 6, and it can be seen that this example uses two colors, green and orange, but this is only an example, and other combinations of colors may be selected according to specific needs.

The SPI-FLASH data storage module 7 is configured to provide data storage services for the main control module 1, and a circuit diagram thereof is shown in fig. 7.

The wireless data transmission module 8 is used for wirelessly connecting with a terminal selected by a user to transmit data sent by the main control module 1 to the terminal, and the circuit diagram is shown in fig. 8. The wireless data transmission module 8 of the present embodiment is based on the bluetooth connection. The user terminal is an intelligent terminal with Bluetooth function such as a computer or a tablet personal computer. The terminal is provided with a specially-designed APP, and after the terminal acquires data, a user sleep report, an eye shield use report and the like are displayed on the APP through background processing.

The power module 9 includes a magnetically attracted charging circuit 91, a 5V boost discharging circuit 92, a 3.3V LDO step-down circuit 93, and a battery level monitoring circuit 94. The magnetic charging circuit 91 is used for charging the storage battery. The 5V boost discharging circuit 92 is used for boosting the discharging voltage of the storage battery to output 5V voltage for supplying power to the components requiring 5V voltage power supply. The 3.3V LDO step-down circuit 93 is used to step down the 5V voltage to power components that require 3.3V voltage supply. The battery power monitoring circuit 94 is configured to monitor the power of the battery and feed back the power to the main control module. Fig. 9-1, 9-2, 9-3, and 9-4 are circuit diagrams of a magnetic attraction charging circuit 91, a 5V boost discharging circuit 92, a 3.3V LDO step-down circuit 93, and a battery level monitoring circuit 94, respectively.

The key module 10 is used for realizing a power switch function and function switching. Fig. 10 is a circuit diagram of the key module 10, it can be seen that the key module 10 is only provided with a key, the power can be turned on or off by pressing the key for a long time, and the hypnotic mode can be switched by clicking or double clicking, for example, if the user does not take any action on the key after the program setting is turned on, the data of heart rate, blood oxygen, body movement, etc. of the user are monitored by default for ten minutes, so as to analyze the sleeping state of the user, and further work according to the preset program as exemplified above. At any working time of the eyeshade, the working mode of the eyeshade can be switched by clicking the key, for example, the current unassisted mode of ten minutes is defaulted, and the single-click of the key can directly enter the single-assisted mode aiming at the state of slight sleeping difficulty of the user. If the eye shield is currently operated in a single assist mode with a user's mild difficulty in falling asleep, a single click of the key may enter a double assist mode for a user's moderate difficulty in falling asleep, and a single click may enter a triple assist mode for a user's severe difficulty in falling asleep. While in each auxiliary mode the respective auxiliary module in such auxiliary mode may be adjusted by double clicking the key, such as currently in a double auxiliary mode where the music module 4 and the heating module 5 work together, double clicking the key may switch music, etc. The functions corresponding to the key operation can be set according to specific requirements, and this example is only an example.

The circuit diagram of the main control module 1 of the present embodiment is shown in fig. 11.

In summary, the embodiment of the utility model provides a sleep assisting eyeshade, a heart rate blood oxygen monitoring module, a body movement signal monitoring module, a music module, a heating module and a light module are arranged on the eyeshade worn for assisting sleep, the heart rate blood oxygen monitoring module and the body movement signal monitoring module are used for acquiring heart rate and blood oxygen data before a user falls asleep and body movement signals to judge the state of the user at the moment, the music module, the heating module and the light module are further intelligently controlled according to the state, and the music, eyeball hot compress and the light are three effective sleep assisting means at present. The sleep assisting eyeshade is not limited in use environment, one person can cover the eyeshade, excessive manual operation of a user is not needed, and the sleeping assisting eyeshade is small in size and convenient to carry.

The above examples are preferred embodiments of the present utility model, but the embodiments of the present utility model are not limited to the above examples, and any other changes, modifications, substitutions, combinations, and simplifications that do not depart from the spirit and principle of the present utility model should be made in the equivalent manner, and the embodiments are included in the protection scope of the present utility model.

Claims (10)

1. The sleep assisting eye mask is characterized by comprising a main control module (1), and a heart rate blood oxygen monitoring module (2), a body movement signal monitoring module (3), a music module (4), a heating module (5) and a light module (6) which are connected with the main control module (1);

the heart rate and blood oxygen monitoring module (2) is used for collecting heart rate and blood oxygen data of a user and sending the heart rate and blood oxygen data to the main control module (1);

the body movement signal monitoring module (3) is used for monitoring a body movement signal of a user and sending the body movement signal to the main control module (1);

the main control module (1) is used for controlling the music module (4), the heating module (5) and the light module (6) according to the heart rate and blood oxygen data and the body movement signal;

the music module (4) is used for playing sleep-aiding music under the control of the main control module (1);

the heating module (5) is used for heating under the control of the main control module (1) so as to compress eyes of the user;

the light module (6) is used for starting light under the control of the main control module (1) so as to irradiate eyes of the user.

2. A sleep-assist eye mask as in claim 1, wherein: and the heart rate and blood oxygen monitoring module (2) adopts a MAX30102 blood oxygen and heart rate monitoring module.

3. A sleep-assist eye mask as in claim 1, wherein: and the body movement signal monitoring module (3) adopts an MPU-6050 module.

4. A sleep-assist eye mask as in claim 1, wherein:

the music module (4) comprises a music master control circuit (41), an SD card storage module (42) and a power amplifier module (43) which are connected with the music master control circuit (41);

the music master control circuit (41) adopts NUC505DS13Y as a master control chip;

the SD card storage module (42) is used for storing the sleep-aiding music;

under the control of the main control module (1), the music main control circuit (41) reads the sleep-aiding music and plays the sleep-aiding music through the power amplification module (43).

5. A sleep-assist eye mask as in claim 1, wherein:

the heating module (5) comprises a heating circuit (51) and a temperature sensing circuit (52), wherein the heating circuit (51) is provided with a heating element, and the heating element is connected with a self-recovery fuse;

the temperature sensing circuit (52) measures the temperature of the heating element through the thermistor and feeds back the temperature to the main control module (1), and the main control module (1) adjusts the heating circuit (51) according to the fed-back temperature, so that constant-temperature closed-loop control of the heating element is realized.

6. A sleep-assist eye mask as in claim 1, wherein: the light module (6) is provided with lamp groups with more than two colors.

7. A sleep-assist eye mask as in claim 1, wherein:

the sleep auxiliary eye cover further comprises an SPI-FLASH data storage module (7) connected with the main control module (1) and used for providing data storage service for the main control module (1).

8. A sleep-assist eye mask as in claim 1, wherein:

the sleep assisting eye mask further comprises a wireless data transmission module (8) connected with the main control module (1), wherein the wireless data transmission module (8) is used for being in wireless connection with the terminal selected by the user so as to transmit data sent by the main control module (1) to the terminal.

9. A sleep-assist eye mask as in claim 1, wherein:

the sleep assisting eye cover also comprises a power supply module (9);

the power module (9) comprises a magnetic attraction charging circuit (91), a 5V boosting discharging circuit (92), a 3.3VLDO voltage reducing circuit (93) and a battery electric quantity monitoring circuit (94);

the magnetic charging circuit (91) is used for charging the storage battery;

the 5V boosting discharge circuit (92) is used for boosting the discharge voltage of the storage battery so as to output 5V voltage for supplying power to components needing 5V voltage power supply;

the 3.3V LDO step-down circuit (93) is used for step-down the 5V voltage to output 3.3V voltage for supplying power to components needing 3.3V voltage power supply;

the battery electric quantity monitoring circuit (94) is used for monitoring the electric quantity of the storage battery and feeding back the electric quantity to the main control module (1).

10. A sleep-assist eye mask as in claim 1, wherein:

the sleep auxiliary eye cover further comprises a key module (10) connected with the main control module (1), and the key module (10) is used for realizing the functions of a power switch and the function switching.