WO2018045483A1 - Sleep aid system - Google Patents

Abstract

A sleep aid system, comprising: an intelligent wearable device (10), a mobile terminal (20) and an air temperature regulator (30) that are connected by an electrical signal, wherein: the intelligent wearable device (10) monitors body temperature of a user and transmits the body temperature of the user to the mobile terminal (20); the mobile terminal (20) generates a control instruction according to the body temperature of the user and sends to the air temperature regulator (30); and the air temperature regulator (30) regulates air temperature according to the control instruction. Since the intelligent wearable device (10) constantly obtains the body temperature of a user, the system may constantly send a control instruction to the air temperature controller (30) by means of the mobile terminal (20), so that the air temperature controller (30) may constantly and dynamically adjust the air temperature so as to automatically and adaptively adjust the air temperature along with a change in state of a sleep process of a person.

Description

Sleep aid system Technical field

The invention is used in the field of Internet application technology, in particular, a sleep assist system.

Background technique

Sleep quality is a very important thing for people. In general, people are more likely to enter sleep in a comfortable and familiar situation, so a comfortable sleeping environment is very important.

However, people often suffer from the weather and the environment during sleep, resulting in poor sleep quality. People need to use more daily tools to help sleep when they sleep, such as: pajamas, pillows, etc., especially on hot summer days. When sleeping, not only is it hot and there are many mosquitoes, people also need to use mosquito coils and pupa to drive away mosquitoes to help sleep.

When a person is asleep, a suitable temperature may be required, and a conventional fan or air conditioner can only adjust the temperature by performing a fixed mode according to the setting. However, during sleep, people need different temperature environments to sleep at different stages. Therefore, how to adaptively adjust the sleep assisting device as the state changes during the sleep process of the person is an urgent problem to be solved.

Summary of the invention

In order to solve the technical problem in the related art that the sleep assisting device cannot be adaptively adjusted as the state changes during sleep, the present invention provides a sleep assisting system.

A sleep assisting system comprising: a smart wearable device with an electrical signal connection, a mobile terminal and an air temperature regulator, wherein:

The smart wearable device monitors a user's body temperature and transmits the user's body temperature to the mobile terminal;

The mobile terminal generates a control command according to the user's body temperature, and sends the control command to the air temperature regulator;

The air temperature regulator adjusts an air temperature according to the control command.

In one embodiment, the sleep assistance system determines whether the user's body temperature is greater than a preset temperature, and if greater, generates a cooling control command.

In one embodiment, the smart assisting device is further configured to acquire a user's heart rate and send the user's heart rate to the mobile terminal; the mobile terminal determines whether the user's heart rate is at a preset heart rate Range, if no, generate an adaptive control command.

In one embodiment of the sleep assist system, the air temperature adjuster oscillates the wind direction or transforms the intensity of the wind according to the adaptive control command.

In one embodiment, the smart assisting device is further configured to acquire a user flip frequency and an audio frequency, and send the user flip frequency and the sound frequency to the mobile terminal; the mobile terminal determines The user flips the frequency and whether the sound frequency exceeds a preset frequency, and if so, generates a mosquito repellent control command.

In one embodiment of the sleep assist system, the mobile terminal is provided with a manual control module that generates an adaptive control command or a mosquito control command according to a user selection.

In one embodiment of the sleep assist system, the air temperature regulator includes an audio; the mobile terminal sends a play command to the sound, the sound playing music.

In one embodiment of the sleep assist system, the air temperature regulator includes an alarm clock that is activated according to a preset time.

In one embodiment of the sleep assist system, the air temperature regulator is an electric fan; the electric fan includes: an electric fan body, and a first wireless communication module disposed on the electric fan body, the first micro processing The first wireless communication module receives an instruction sent by the mobile terminal, and the first microprocessor retrieves execution information pre-stored in the first storage module according to the received instruction, and Controlling the execution of the electric fan body.

In one embodiment of the sleep assist system, the electric fan body includes: a fan frame, a fan blade, a fan cover, a fan motor, a motor positioning screw, and a fan switch; the fan motor passes the fan blade and the motor positioning screw The fan frame is integrally connected, the fan cover is disposed on the fan blade, the fan switch is electrically connected to the fan motor, and the fan switch is controlled to be turned on or off.

In one embodiment of the sleep assist system, the electric fan further includes: a heating wire connected to the power source, the first microprocessor controlling the heating wire to generate heat.

In one embodiment of the sleep assist system, the electric fan further includes: a mosquito repellent device connected to the power source, the mosquito repellent device including a power grid and a lamp tube, the first microprocessor controlling the opening of the power grid and the lamp tube Or close.

In one embodiment of the sleep assist system, the air temperature regulator is an air conditioner or an air conditioner fan.

In one embodiment, the smart assisting device includes: a temperature sensor, a second microprocessor, a second wireless communication module, a second storage module, and a power module; the temperature sensor acquires a user's body temperature, The second microprocessor stores the acquired user body temperature data in the second And storing, by the second wireless communication module, the mobile terminal, wherein the power module is the temperature sensor, the second microprocessor, the second wireless communication module, and the second storage The module provides electrical energy.

In one embodiment of the sleep assist system, the smart wearable device further includes a heart rate sensor that acquires a user heart rate.

In one embodiment of the sleep assist system, the smart wearable device further includes: a gravity sensor and a sound sensor; the gravity sensor acquires a user flip frequency, and the sound sensor acquires an audio frequency.

The user's body temperature is obtained by setting a smart wearable device on the user, and the user's body temperature data is processed by the mobile terminal to obtain an optimal human body sleep temperature and generate a control command, and the air temperature adjuster adjusts the air temperature according to the control command. Since the smart wearable device obtains the user's body temperature at any time, the mobile terminal can send the control command to the air temperature adjuster at any time, and the air temperature adjuster can adjust the air temperature at the moment and dynamically, thereby realizing the follow-up of the person. The state of the sleep changes and adaptively adjusts the air temperature, instead of adjusting the air temperature in response to changes in the ambient temperature, to achieve accurate assisted user sleep.

The above general description and the following detailed description are merely exemplary and are not intended to limit the disclosure.

DRAWINGS

The accompanying drawings, which are incorporated in and constitute in FIG

Figure 1 is a schematic diagram of a sleep assist system in one embodiment;

2 is a diagram showing an example of the relationship between heart rate and body temperature in three stages during sleep in one embodiment;

Figure 3 is a logic diagram of an electric fan in an embodiment;

4 is a logic diagram of a smart wearable device in one embodiment.

detailed description

The description will be made in detail herein with respect to exemplary embodiments, examples of which are illustrated in the accompanying drawings. The following description refers to the same or similar elements in the different figures unless otherwise indicated. The embodiments described in the following exemplary embodiments do not represent all embodiments consistent with the present invention. formula. Rather, they are merely examples of devices consistent with aspects of the invention as detailed in the appended claims.

In one embodiment, as shown in FIG. 1, a sleep assist system includes: an intelligent wearable device 10 connected to an electrical signal, a mobile terminal 20, and an air temperature adjuster 30, wherein:

The smart wearable device 10 monitors the user's body temperature and transmits the user's body temperature data to the mobile terminal 20. Specifically, the smart wearable device 10 can be fixed to the user by a strap, or can be cleverly designed to be integrated with a component related to sleep, such as a button of a pajamas. Further, the smart wearable device 10 sets the position in contact with the body surface as much as possible, so as to accurately obtain the user's body temperature. It can be understood that the smart wearable device 10 monitors the user's body temperature can be obtained "at the moment", however, the "time" can be time-to-time, or can be based on a preset time interval, for example, every 10 seconds, every 1 minute, or every 5 minutes, etc. The time interval can be set according to the needs of the user.

The mobile terminal 20 generates a control command based on the user's body temperature and transmits it to the air temperature adjuster 30. Specifically, the mobile terminal 20 may be a smart phone, a PAD, a notebook computer, or the like. The mobile terminal 20 receives the user's body temperature transmitted by the smart wearable device 10, and generates a relative control command according to the pre-stored condition, and transmits it to the air temperature adjuster 30.

An air temperature regulator 30 that regulates the air temperature in accordance with a control command. Specifically, the air temperature regulator 30 may be any device that can adjust the air temperature, such as an air conditioner, a fan, or an air conditioner fan, which performs temperature regulation according to an instruction.

The user's body temperature is obtained by setting the smart wearable device 10 on the user, and the user's body temperature data is processed by the mobile terminal 20 to obtain an optimal human body sleep temperature and generate a control command, and the air temperature adjuster 30 determines the air temperature according to the control command. Make adjustments. Since the smart wearable device 10 obtains the user's body temperature at any time, the mobile terminal 20 can timely send a control command to the air temperature adjuster 30, and the air temperature adjuster 30 can realize the time and dynamic adjustment of the air temperature, thereby realizing As the state of the person's sleep changes, the air temperature is adaptively adjusted, instead of following the change of the ambient temperature, the air temperature is adjusted to achieve accurate auxiliary user sleep.

In an embodiment, the mobile terminal 20 has a data operation processing capability. When the mobile terminal 20 receives the user's body temperature sent by the smart wearable device 10, the mobile terminal 20 determines whether the user's body temperature is greater than a preset temperature. If the control command is less than, the command to stop cooling or the command to generate heating is generated. It can be understood that for users with different physiques and different living habits, Only the user is sensitive to his or her body temperature, and the user knows whether he is "comfortable", so set the preset temperature associated with the user's own body temperature to regulate the user's most "comfortable" ambient temperature. For example, a normal temperature of a person is 36 to 37 degrees, and some users think that 35.8 degrees is the most suitable sleep temperature. When the sleep temperature does not reach 35.8 degrees, the mobile terminal 20 generates a cooling control command through the air temperature adjuster 30. Adjust the ambient temperature.

Further, the smart wearable device 10 is further configured to acquire a user's heart rate and send the user's heart rate to the mobile terminal 20; the mobile terminal 20 determines whether the user's heart rate is within a preset heart rate range, and if not, generates an adaptive control command. When a person sleeps, they have different sleep states. When the user is deeply asleep, the heart rate of the user is generally the lowest value during the sleep process, and the heart rate range often has its optimal range value, for example, the heart rate is 70-80 times/minute. . The generated adaptive control command may be that the air temperature adjuster 30 oscillates the wind direction or changes the intensity of the wind according to the adaptive control command until the optimal user heart rate is reached.

Furthermore, in conjunction with FIG. 2, in order to better provide a user with a good sleeping environment, the user's heart rate is correlated with the body temperature, and an integrated control command is output. Specifically, during the sleep process, a person can be divided into three stages, a sleep stage, a deep sleep stage, and a gradual recovery stage; during the sleep stage, the difference between the heart rate value and the body temperature fluctuation value should be maintained in the range of “positive and negative 1”. In the deep sleep stage, the difference between the heart rate value and the body temperature fluctuation value should be kept in the range of “positive and negative 0.1”; in the gradual recovery phase, the difference between the heart rate value and the body temperature fluctuation value should be kept in the range of “plus or minus 0.5”. If the fluctuation of the heart rate and the body temperature obtained by the smart wearable device 10 is not within this range, an integrated control command is issued to the air temperature adjuster 30. For example, the integrated control commands include cooling, heating, wind direction, wind strength, etc. When the above requirements are met, a stop command is issued. It should be noted that the difference between the heart rate value and the body temperature fluctuation value = the difference between the heart rate and the body temperature at each collection point at the stage; the numerical difference between the heart rate and the body temperature = the numerical difference between the heart rate and the body temperature.

In order to better illustrate the scheme, it is explained by a specific example (three values are collected at each stage, of course, multiple values can be collected at each stage as needed), as follows:

In an embodiment, the smart wearable device 10 is further configured to acquire a user flip frequency and an audio frequency, and send the user flip frequency and the sound frequency to the mobile terminal 20; the mobile terminal 20 determines whether the user flip frequency and the sound frequency exceed a preset value. Frequency, if yes, generate a mosquito repellent control command. Specifically, it can be judged that the person is uncomfortable during the sleep process by the frequency of the person's inversion. In addition, the frequency of the sound is mainly for the bite of the mosquito, the sound of the "beep" generated by the person during the tapping process, and the like The sound has its specific frequency and loudness, that is, the peak of the sound is higher, the frequency is higher, and the time is also very short. These sounds and the frequency of flipping all reflect mosquitoes in the sleeping environment, thus generating mosquito repellent control commands. It should be noted that the frequency of user flipping and the frequency of sound can be set according to the needs of the user. In other embodiments, the mobile terminal 20 is provided with a manual control module (not shown), and the manual control module generates an adaptive control command or a mosquito control command according to a user selection.

In an embodiment, in conjunction with FIG. 3, the air temperature regulator 30 is an electric fan; the electric fan (not shown) includes: an electric fan body (not shown), and a first wireless communication disposed on the electric fan body. The module 32, the first microprocessor 31, and the first storage module 33; the first wireless communication module 32 receives the instruction sent by the mobile terminal 20, and the first microprocessor 31 retrieves the pre-stored in the first storage module 33 according to the received instruction. Execution information and control of the fan body execution.

Further, the fan body includes: a fan frame (not shown), a fan blade 381, a fan cover (not shown), a fan motor 38, a motor positioning screw (not shown), and a fan switch 37; the fan motor 38 passes the motor The positioning screw integrally connects the fan blade 381 and the fan frame, the fan cover covers the fan blade 381, and the fan switch 37 is electrically connected to the fan motor 38. The fan switch 37 controls the opening or closing. In addition, the fan motor 38 includes an upper and lower stepping motor (not shown) and a left and right stepping motor (not shown) for controlling the fan blade 381 to swing up and down and left and right.

In other embodiments, the electric fan further includes: a heating wire 36 connected to the power source, and the first microprocessor 31 controls the heating wire 36 to generate heat. A mosquito repellent device 39 connected to a power source, the mosquito repellent device 39 includes a power grid 392 and a lamp tube 391, and the first microprocessor 31 controls the opening or closing of the power grid 392 and the lamp tube 391. specifically, The heating wire 36 can increase the temperature of the surrounding environment, and can also be used for drying other functions such as hair; in addition, the grid 392 in the mosquito repellent device 39 is a weak voltage grid 392 for removing mosquitoes, and the lamp 391 is blue/purple. Used to attract mosquitoes to the grid 392.

In addition, the air temperature adjuster 30 includes an audio 34; the mobile terminal 20 transmits a play command to the sound 34, and the sound 34 plays music. The air temperature regulator 30 includes an alarm 35 that is activated according to a preset time. The setting has manual control and multiple functions to enrich the control mode and function of the air temperature regulator 30. In the present embodiment, the air temperature regulator 30 is an electric fan.

In an embodiment, with reference to FIG. 4, the smart wearable device 10 includes: a temperature sensor 12, a second microprocessor 11, a second wireless communication module 18, a second storage module 16, and a power module 17; The user's body temperature, the second microprocessor 11 stores the acquired user's body temperature data in the second storage module 16, and sends it to the mobile terminal 20 through the second wireless communication module 18, the power module is the temperature sensor 12, the second microprocessor 11. The second wireless communication module 18 and the second storage module 16 provide electrical energy.

Further, the smart wearable device 10 further includes a heart rate sensor 13 that acquires the user's heart rate. In other embodiments, the smart wearable device 10 further includes: a gravity sensor 15 and a sound sensor 14; the gravity sensor 15 acquires the user's flip frequency, and the sound sensor 14 acquires the sound frequency. Specifically, the gravity sensor 15 can sense the gravity change of the person according to the flipping action of the person, thereby determining the flip frequency of the person, and transmitting the information of the flip frequency to the mobile terminal 20. Further, the sound sensor 14 captures the sound by capturing the sound in the air, and if the specific frequency, loudness, and time are satisfied, the sound is recorded once, and the information of the sound frequency is transmitted to the mobile terminal 20. The smart wearable device 10 with multiple sensors provides convenience for monitoring and collecting a variety of human body information, and lays a foundation for accurately providing sleep assisting functions.

In other embodiments, the smart wearable device 10 can be directly electrically coupled to the air temperature adjuster 30 via the second wireless communication module 18 to integrate the functions of the mobile terminal 20 in the air temperature adjuster 30.

It is to be understood that the invention is not limited to the details of the details and The scope of the invention is limited only by the appended claims.

Claims (16)

A sleep assisting system, comprising: a smart wearable device with an electrical signal connection, a mobile terminal and an air temperature regulator, wherein: The smart wearable device monitors a user's body temperature and transmits the user's body temperature to the mobile terminal; The mobile terminal generates a control command according to the user's body temperature, and sends the control command to the air temperature regulator; The air temperature regulator adjusts an air temperature according to the control command. The sleep assist system according to claim 1, wherein the mobile terminal determines whether the user's body temperature is greater than a preset temperature, and if greater, generates a cooling control command. The sleep assisting system according to claim 1, wherein the smart wearable device is further configured to acquire a user's heart rate and send the user's heart rate to the mobile terminal; and the mobile terminal determines whether the user's heart rate is In the preset heart rate range, if not, an adaptive control command is generated. The sleep assist system according to claim 3, wherein the air temperature adjuster oscillates the wind direction or changes the intensity of the wind according to the adaptive control command. The sleep assisting system according to claim 1, wherein the smart wearable device is further configured to acquire a user flip frequency and an audio frequency, and send the user flip frequency and the sound frequency to the mobile terminal; The mobile terminal determines whether the user flips the frequency and whether the sound frequency exceeds a preset frequency, and if so, generates a mosquito repellent control command. The sleep assist system according to claim 1, wherein the mobile terminal is provided with a manual control module, and the manual control module generates an adaptive control command or a mosquito control command according to a user selection. The sleep assist system according to claim 1, wherein said air temperature adjuster comprises an audio; said mobile terminal transmits a play command to said sound, said sound playing music. The sleep aid system of claim 1, wherein the air temperature adjuster comprises an alarm clock that is activated according to a preset time. The sleep assist system according to any one of claims 1 to 8, wherein the air temperature regulator is an electric fan; The electric fan includes: an electric fan body, and a first wireless communication module disposed on the electric fan body, a first microprocessor, and a first storage module; and the first wireless communication module receives the mobile terminal to send And the first microprocessor is pre-stored in the first according to the received instruction The execution information of the storage module is stored, and the execution of the electric fan body is controlled. The sleep assist system according to claim 9, wherein the electric fan body comprises: a fan frame, a fan blade, a fan cover, a fan motor, a motor positioning screw, and a fan switch; The fan motor is integrally connected to the fan blade by the motor positioning screw, the fan cover is disposed on the fan blade, and the fan switch is electrically connected to the fan motor, The fan switch control is turned on or off. The sleep assist system according to claim 10, wherein the electric fan further comprises: a heating wire connected to the power source, wherein the first microprocessor controls the heating wire to generate heat. The sleep assisting system according to claim 10, wherein the electric fan further comprises: a mosquito repellent device connected to the power source, the mosquito repellent device comprising a power grid and a lamp tube, the first microprocessor controlling the power grid And the light tube is turned on or off. The sleep assist system according to any one of claims 1 to 8, characterized in that the air temperature adjuster is an air conditioner or an air conditioner fan. The sleep assisting system according to any one of claims 1 to 8, wherein the smart wearable device comprises: a temperature sensor, a second microprocessor, a second wireless communication module, a second storage module, and a power module. The temperature sensor acquires a body temperature of the user, the second microprocessor stores the acquired user body temperature data in the second storage module, and sends the data to the mobile terminal through the second wireless communication module, The power module provides power to the temperature sensor, the second microprocessor, the second wireless communication module, and the second storage module. The sleep assist system according to claim 14, wherein the smart wearable device further comprises: a heart rate sensor, wherein the heart rate sensor acquires a user heart rate. The sleep assisting system according to claim 14, wherein the smart wearable device further comprises: a gravity sensor and a sound sensor; the gravity sensor acquires a frequency of user flipping, and the sound sensor acquires an audio frequency.

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