CN114468665A - Multifunctional graphene mattress - Google Patents

Abstract

The invention discloses a multifunctional graphene mattress, which comprises a bearing base cushion and a heating massage system, wherein a cavity array is arranged on the bearing base cushion and consists of mutually independent unit cavities, a unit air bag body is arranged in each unit cavity, each unit air bag body is connected with a unit air pressure distributor through an independent gas pipeline, and a unit graphene power generation heat film is sleeved outside each independent gas pipeline; the unit graphene power generation thermal film is used for heating gas entering the unit gas bag body. The unit air sac body, the target unit air pressure distributor and the target unit graphene power generation thermal film are controlled by the control module through providing the unit air sac body for each independent unit air sac body. Thereby realizing a hot massage mode and having good feeling for users. The invention is mainly used in the technical field of household application.

Description

Multifunctional graphene mattress

Technical Field

The invention relates to the technical field of household application, in particular to a multifunctional graphene mattress.

Background

The development of science and technology enables people to continuously improve the pursuit of life quality and people to gradually improve the pursuit of comfortable sleep, good sleep quality can enhance immunity and eliminate fatigue, and the quality of the sleep quality is closely related to a mattress. Currently, many technicians have to improve the functions of the mattress in terms of life needs, such as adding a massage function to the mattress to relieve the working fatigue of the user, adding a warming function to the mattress to relieve the winter discomfort of the user, and the like. However, in the design of the heat preservation function, the electric blanket is usually tiled on the mattress directly, and the electric heating wire arranged in the electric blanket is used for heating, so that potential safety hazards are easily caused and the heating effect is not adjustable; often adopt the massage ball to set up in mattress inside vibration contact massage in the design of massage function, but user's comfort is not good.

Disclosure of Invention

The invention provides a multifunctional graphene mattress, which is used for solving one or more technical problems in the prior art and at least providing a beneficial selection or creation condition.

The invention provides a multifunctional graphene mattress, which comprises a bearing base cushion and a heating massage system, wherein a cavity array is arranged on the bearing base cushion and consists of mutually independent unit cavities, a unit air bag body is arranged in each unit cavity, each unit air bag body is connected with a unit air pressure distributor through an independent gas pipeline, and a unit graphene power generation heat film is sleeved outside each independent gas pipeline; the unit graphene power generation thermal film is used for heating gas entering the unit gas bag body;

the unit air bag body is used for bulging from the unit cavity through expansion, the front edge of the bulge of the unit air bag body is provided with a temperature conducting part, and the temperature conducting part is used for conducting the gas temperature in the unit air bag body;

the heating massage system comprises an air pressure source device, a control module and an identification device;

the air pressure source device is respectively connected with the unit air pressure distributor and is used for providing set air pressure for the unit air pressure distributor; the unit air pressure distributor performs air pressure distribution on the target unit air sac body connected with the unit air pressure distributor, the unit air pressure distributor sets air pressure or zero air pressure for the target unit air sac body, when the set air pressure is distributed, the target unit air sac body expands, and when the zero air pressure is distributed, the target unit air sac body does not expand;

the identification device is used for acquiring an occupied area of a user lying on the top surface of the bearing base cushion, the control module is used for acquiring a unit air bag body needing to be controlled according to the occupied area, the unit air bag body is marked as a target unit air bag body, a unit graphene power generation heat film corresponding to the target unit air bag body is marked as a target unit graphene power generation heat film, and a unit air pressure distributor corresponding to the target unit air bag body is marked as a target unit air pressure distributor;

the control module is used for controlling the target unit air pressure distributor to carry out air pressure distribution on the target unit air bag body connected with the target unit air pressure distributor so as to control the expansion frequency of the target unit air bag body;

the control module is used for controlling the gas temperature in the target unit air bag body by adjusting the heating temperature of the target unit graphene power generation hot film.

Further, the multifunctional graphene mattress also comprises a frequency input module, wherein the frequency input module is connected with the control module and is used for receiving target expansion frequency input by a user;

the frequency input module updates the target expansion frequency input by a user, the control module acquires the target expansion frequency from the frequency input module when confirming that the target expansion frequency input by the user is updated, and the control module controls the target unit air pressure distributor to perform air pressure distribution on the target unit air bag body connected with the target unit air bag distributor so as to control the expansion frequency of the target unit air bag body to be adjusted to the target expansion frequency.

Further, the multifunctional graphene mattress also comprises a temperature input module, wherein the temperature input module is connected with the control module and is used for receiving a target temperature input by a user;

the temperature input module updates the target temperature input by a user, the control module acquires the target temperature from the temperature input module when confirming that the target temperature input by the user is updated, and the control module controls the target unit graphene power generation thermal film so that the gas temperature in the target unit gas bag body reaches the target temperature.

Further, the identifying means for obtaining an occupied area of a user lying on the top surface of the load-bearing base pad specifically comprises: the recognition device shoots a top view of a user lying on the bearing top surface of the bearing base pad, extracts the outline of the user according to the top view, and the area surrounded by the outline on the top surface is an occupied area.

Further, the control module is used for obtaining the unit airbag body needing to be controlled according to the occupied area and specifically comprises: the control module establishes a corresponding plane coordinate system by taking the top surface of the bearing base pad as a datum plane, and obtains the whole coordinate range of the occupied area in the plane coordinate system;

and acquiring the coordinate information of each unit airbag body installed in the cavity array in the plane coordinate system, and further screening out all unit airbag bodies of which the coordinate information falls in the whole coordinate range to obtain the unit airbag body which is the unit airbag body required to be controlled.

The music playing system is used for obtaining the target expansion frequency of the unit air bag body, visiting a cloud music website to obtain a daily recommended song list, playing the last time to randomly select the songs in the daily recommended song list according to the number value of the target expansion frequency as the number of times of randomly selecting the songs in the daily recommended song list.

Furthermore, the control module is a control system with a single chip microcomputer as a core.

Further, the singlechip includes STM32 singlechip.

Further, this multi-functional graphite alkene mattress still includes intelligent sleep monitor system, intelligent sleep monitor system is used for real-time supervision to include: the heart rate value of the user lying on the bearing base pad, the breathing rate of the user lying on the bearing base pad, the time that the user leaves the bearing base pad, the duration that the user stays on the bearing base pad and the ambient temperature of the environment where the bearing base pad is located, and will the heart rate value of the user lying on the bearing base pad, the breathing rate of the user lying on the bearing base pad, the time that the user leaves the bearing base pad, the duration that the user stays on the bearing base pad and the ambient temperature of the environment where the bearing base pad is located are uploaded to the remote server in real time.

The invention has at least the following beneficial effects: the unit air sac body, the target unit air pressure distributor and the target unit graphene power generation thermal film are controlled by the control module through providing the unit air sac body for each independent unit air sac body. Thereby realizing a hot massage mode and having good feeling for users.

Drawings

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the example serve to explain the principles of the invention and not to limit the invention.

FIG. 1 is a schematic diagram of a system architecture of a multifunctional graphene mattress;

FIG. 2 is a schematic perspective view of a load-bearing base pad;

figure 3 is a schematic illustration of an exploded structure of a load-bearing base pad.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It should be noted that although functional block divisions are provided in the system drawings and logical orders are shown in the flowcharts, in some cases, the steps shown and described may be performed in different orders than the block divisions in the systems or in the flowcharts. The terms first, second and the like in the description and in the claims, and the drawings described above, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order.

Referring to fig. 1 to 3, an embodiment of the present invention provides a multifunctional graphene mattress, including a bearing base pad 100 and a heating massage system, wherein a cavity array 110 is disposed on the bearing base pad 100, the cavity array 110 is composed of mutually independent unit cavities, a unit air bag is installed in each unit cavity, each unit air bag is connected to a unit air pressure dispenser 120 through an independent air pipe, and a unit graphene power generation thermal film 130 is sleeved outside each independent air pipe; the unit graphene power generation thermal film 130 is used for heating gas entering the inside of the unit airbag body.

The unit air bag body is used for bulging from the unit cavity through expansion, the front edge of the bulge of the unit air bag body is provided with a temperature conducting part, and the temperature conducting part is used for conducting the gas temperature in the unit air bag body; the heating massage system comprises an air pressure source device 400, a control module 210 and an identification device 300; the air pressure source device 400 is respectively connected with the unit air pressure distributor 120, and the air pressure source device 400 is used for providing set air pressure for the unit air pressure distributor 120; the unit air pressure dispenser 120 performs air pressure dispensing on the target unit air sac body connected with the unit air pressure dispenser 120, the unit air pressure dispenser 120 sets air pressure or zero air pressure for dispensing on the target unit air sac body, when the set air pressure is dispensed, the target unit air sac body is expanded, and when the zero air pressure is dispensed, the target unit air sac body is not expanded.

The identification device 300 is configured to obtain an occupied area of the load-bearing base pad 100 on which a user lies, the control module 210 is configured to obtain a unit airbag body to be controlled according to the occupied area, the unit airbag body is recorded as a target unit airbag body, the unit graphene power generation thermal film 130 corresponding to the target unit airbag body is recorded as a target unit graphene power generation thermal film, and the unit air pressure dispenser 120 corresponding to the target unit airbag body is recorded as a target unit air pressure dispenser.

The control module 210 is used to control the target unit air pressure dispenser to perform air pressure distribution on the target unit air bag body connected thereto, so as to control the expansion frequency of the target unit air bag body.

The control module 210 is configured to control the gas temperature inside the target unit gas bag body by adjusting the heating temperature of the target unit graphene power generation thermal film.

In the embodiment of the present invention, the cavity array 110 is disposed on the top surface of the load-bearing base 100, and each unit pneumatic dispenser 120 is disposed inside the lower side of the load-bearing base 100. Each unit pneumatic dispenser 120 corresponds to the position of each unit air cell body, and a gas pipe between each unit pneumatic dispenser 120 and the corresponding unit air cell body vertically passes through the bottom surface of the load-bearing base pad 100. Each gas pipeline is sleeved with a unit graphene power generation thermal film 130.

The air pressure source unit 400 is used to supply air pressure to each unit air pressure dispenser 120. In operation, the air pressure source device 400 is used to generate a set air pressure and input the set air pressure to the unit air pressure dispenser 120. The unit pneumatic dispenser 120 can have two pneumatic output states by being controlled. The first air pressure output state is to completely input the set air pressure generated by the air pressure source device 400 into the unit air cell body. The second air pressure output state is that the set air pressure generated by the air pressure source device 400 is not inputted into the unit air cell body. For the first air pressure output state, the unit air bag body is fully expanded, and when the unit air bag body is fully expanded, the temperature guide part of the unit air bag body can be contacted with the body of a user, so that the temperature of the air in the unit air bag body is conducted to the body of the user, and the function of thermal massage is achieved. In the second air pressure output state, the unit air bag bodies are not expanded when being contracted, and therefore, the temperature guide portions of the unit air bag bodies are not in contact with the body of the user in the second air pressure output state.

By setting the frequency of the contact between the unit air bag body and the body, the dynamic thermal massage effect can be realized. The multifunctional graphene mattress is also based on the massage mode to improve the user experience. In some embodiments, the control module 210 is configured to control the unit pneumatic dispenser 120 so as to control the unit pneumatic dispenser 120 to switch between two pneumatic output states. Meanwhile, the unit air pressure dispenser 120 is controlled to switch the frequency of the two air pressure output states to achieve the thermal massage effect. The present embodiment describes the switching frequency by using the parameter of the frequency of the dilation. Of course, in the case of heat massage of the user, it is necessary to determine the lying area of the user lying on the top surface of the load-bearing base pad 100, which is referred to as the occupied area in the present invention. When the occupied area is determined, the unit airbag body in the occupied area can be controlled. The unit cell body to be controlled is referred to as a target unit cell body. After determining the target unit air bag body, the control module 210 may control the target unit air pressure dispenser corresponding to the target unit air bag body, and may also control the target unit graphene power generation thermal film corresponding to the target unit air bag body.

The control module 210 controls the target unit air pressure dispenser to control the expansion frequency of the target unit air bag body, and the control module 210 controls the target unit graphene power generation thermal film to control the gas temperature inside the target unit air bag body. Through the control to the heating of target unit atmospheric pressure distributor and target unit graphite alkene, realized the function of hot massage, promoted user experience.

In order to facilitate the adjustment of the expansion frequency by the user, in some preferred embodiments, the multifunctional graphene mattress further includes a frequency input module 220, the frequency input module 220 is connected to the control module 210, and the frequency input module 220 is configured to receive a target expansion frequency input by the user.

The frequency input module 220 updates the target expansion frequency input by the user, when the control module 210 confirms that the target expansion frequency input by the user is updated, the control module 210 acquires the target expansion frequency from the frequency input module 220, and the control module 210 controls the unit air pressure dispenser 120 to perform air pressure distribution on the unit air bag body connected with the unit air pressure dispenser so as to control the expansion frequency of the unit air bag body to be adjusted to the target expansion frequency.

The frequency input module 220 is a human-computer interaction module, and the frequency input module 220 is used for acquiring the target expansion frequency input by the user. When the frequency input module 220 obtains the target expansion frequency, the previous target expansion frequency is updated. The control module 210 knows that the frequency input module 220 has updated the target inflation frequency, and then accesses the frequency input module 220 to obtain the updated target inflation frequency from the frequency input module 220. The control module 210 controls the target unit balloon body according to the target inflation frequency. So that the expansion frequency of the target unit air sac body is adjusted to the target expansion frequency. Thereby, the effect of thermal massage can be changed according to the self demand of the user.

In order to further improve the user experience, the temperature of the thermal massage can be adjusted. In some specific preferred embodiments, the multifunctional graphene mattress further includes a temperature input module 230, the temperature input module 230 is connected to the control module 210, and the temperature input module 230 is configured to receive a target temperature input by a user.

The temperature input module 230 updates the target temperature input by the user, when the control module 210 confirms that the target temperature input by the user is updated, the control module 210 obtains the target temperature from the temperature input module 230, and the control module 210 controls the target unit graphene power generation thermal film, so that the gas temperature inside the target unit gas bag body reaches the target temperature.

The temperature input module 230 is a human-computer interaction module, and the temperature input module 230 is used for acquiring a target temperature input by a user. When the temperature input module 230 obtains the target temperature, it updates the target temperature obtained previously. After knowing that the temperature input module 230 has updated the target temperature, the control module 210 accesses the temperature input module 230 to obtain the updated target temperature from the temperature input module 230. The control module 210 controls the target unit graphene power generation thermal film according to the target temperature. So that the gas temperature inside the target unit gas bag body reaches the target temperature. Thereby, the effect of thermal massage can be changed according to the self demand of the user.

In some preferred embodiments, the step of identifying the occupied area of the user lying on the top surface of the base load-bearing mat 100 by the identification device 300 comprises: the recognition device 300 photographs a top view of a user lying on the top surface of the load-bearing base pad 100, and extracts a user's outline from the top view, wherein an area surrounded by the outline on the top surface is an occupied area.

The contour of the user can be extracted according to the top view by adopting a contour extraction algorithm in the prior art, and the contour of the user can be extracted through the contour extraction algorithm. After the user's outline is extracted, the area on the top surface surrounded by the user's outline can be regarded as an occupied area. The occupancy area may reflect the user's lying position to determine which unit cell bodies are required as controlled unit cell bodies.

In some preferred specific embodiments, the obtaining, by the control module 210, the unit airbag body to be controlled according to the occupied area specifically includes: the control module 210 establishes a corresponding plane coordinate system by using the top surface of the load-bearing base pad 100 as a reference surface, and obtains an overall coordinate range of the occupied area in the plane coordinate system.

And acquiring coordinate information of each unit airbag body installed in the cavity array 110 in the plane coordinate system, and further screening out all unit airbag bodies of which the coordinate information falls in the whole coordinate range to obtain the unit airbag body which is the unit airbag body required to be controlled.

In these embodiments, the control module 210 establishes a corresponding planar coordinate system by using the top surface of the load-bearing base pad 100 as a reference surface, so that each position of the load-bearing base pad 100 can be quantitatively described. And then, the overall coordinate range of the occupied area in the plane coordinate system is obtained, so that the position condition of the occupied area on the top surface of the load-bearing base pad 100 is described. For each unit air bag body, the coordinate information of the unit air bag body in the plane coordinate system can be set in advance, so that the unit air bag body and the plane coordinate system can be associated. So that the unit gas cell body can be described by the coordinate information. After the coordinate information of the unit balloon body is obtained, the coordinate information can be screened. And screening out the unit air bag body of which the coordinate information falls in the whole coordinate range, wherein the unit air bag body is the unit air bag body needing to be controlled.

Of course, in the above-described specific embodiment, the unit airbag body falling into the occupied area can be found well by the coordinate information. However, since the solution adopted in this embodiment describes the unit gas cell body only by the coordinate information. To a large extent, one unit balloon body corresponds to one piece of coordinate information. However, the unit airbag bodies have a range, and if one unit airbag body is described by only one piece of coordinate information, some unit airbag bodies at the edge of the occupied area are not judged to fall into the occupied area. In practical cases, the unit airbag body at the edge of the occupied area may also affect the body of the user, and may contact the body of the user. Therefore, how to judge the unit airbag body at the edge of the occupied area as the unit airbag body to be controlled becomes a problem to be paid attention.

To solve this problem, in some embodiments, the control module 210 performs a lattice process on the top surface of the load-bearing base pad 100 to obtain a lattice surface, draws the occupied area on the lattice surface, and refers to a set of unit points surrounded by the outline of the occupied area as a target set of unit points.

And marking unit points of the area where the orifices of the unit cavities are positioned in the point array surface, wherein the set of the unit points of the area where the orifices of the same unit cavity are positioned is called a unit air bag body unit point set, and one unit air bag body unit point set corresponds to one unit air bag body.

Screening out a unit air sac body unit point set belonging to the target unit point set, and finding out a unit air sac body corresponding to the unit air sac body unit point set, wherein the corresponding unit air sac body is a unit air sac body needing to be controlled.

The screening rule of the unit airbag body unit point set belonging to the target unit point set is as follows: if more than 70% of the unit spots in the unit cell collection of the unit gas bag body belong to the target unit spot collection, the unit cell collection of the unit gas bag body is considered to belong to the target unit spot collection.

The occupied area is thinned by arranging the point array surface, and the position of the unit air sac body is described by using a unit air sac body unit point set mode in consideration of the fact that the unit air sac body has a certain size. Further, it is defined that a unit cell set of the unit gas cell body is considered to belong to a target unit cell set as long as 70% or more of the unit cells in the unit cell set belong to the target unit cell set. The specific embodiment can solve the technical problem of how to judge the unit air bag body at the edge of the occupied area as the unit air bag body needing to be controlled.

In some preferred embodiments, the multifunctional graphene mattress further includes a music playing system 500, where the music playing system 500 is configured to obtain a target expansion frequency of the unit air bag, access a cloud music website to obtain a daily recommended song list, use the number value of the target expansion frequency as the number of times of randomly selecting songs in the daily recommended song list, and play the last time of randomly selecting songs in the daily recommended song list.

The music playing system 500 functions to randomly play songs on a cloud music website, and is random in order to achieve randomness. The music playback system 500 takes the target overrun as a random basis and takes the value of the target overrun as the number of times the song is randomly selected. And playing the randomly acquired song for the last time. By adding the target dilation frequency to the stochastic process. The random selection of the songs is associated with the hot massage process, so that both random factors and determining factors exist in the song selection process, and the songs are better randomly selected.

For the control module 210, in some preferred embodiments, the control module 210 is a control system with a single chip microcomputer as a core. Wherein, the singlechip includes STM32 singlechip.

In some preferred embodiments, the multifunctional graphene mattress further includes an intelligent sleep monitoring system 600, and the intelligent sleep monitoring system 600 is configured to monitor in real time, and includes: the heart rate value of the user lying on the load-bearing base pad 100, the breathing rate of the user lying on the load-bearing base pad 100, the time for the user to leave the load-bearing base pad 100, the length of time the user stays on the load-bearing base pad 100, and the ambient temperature of the environment in which the load-bearing base pad 100 is located, and the heart rate value of the user lying on the load-bearing base pad 100, the breathing rate of the user lying on the load-bearing base pad 100, the time for the user to leave the load-bearing base pad 100, the length of time the user stays on the load-bearing base pad 100, and the ambient temperature of the environment in which the load-bearing base pad 100 is located are uploaded to the remote server in real time. The remote server may analyze the sleep quality of the user based on the heart rate value of the user lying on the load-bearing base pad 100, the breathing rate of the user lying on the load-bearing base pad 100, the time the user leaves the load-bearing base pad 100, the length of time the user remains on the load-bearing base pad 100, and the ambient temperature of the environment in which the load-bearing base pad 100 is located, thereby forming an analysis report for the user to read.

While the description of the present application has been made in considerable detail and with particular reference to a few illustrated embodiments, it is not intended to be limited to any such details or embodiments or any particular embodiments, but it is to be construed that the present application effectively covers the intended scope of the application by reference to the appended claims, which are interpreted in view of the broad potential of the prior art. Further, the foregoing describes the present application in terms of embodiments foreseen by the inventor for which an enabling description was available, notwithstanding that insubstantial changes from the present application, not presently foreseen, may nonetheless represent equivalents thereto.

Claims (9)

1. A multifunctional graphene mattress is characterized by comprising a bearing base cushion and a heating massage system, wherein a cavity array is arranged on the bearing base cushion and consists of mutually independent unit cavities, a unit air bag body is arranged in each unit cavity, each unit air bag body is connected with a unit air pressure distributor through an independent gas pipeline, and a unit graphene power generation heat film is sleeved outside each independent gas pipeline; the unit graphene power generation thermal film is used for heating gas entering the unit gas bag body;

the unit air bag body is used for bulging from the unit cavity through expansion, the front edge of the bulge of the unit air bag body is provided with a temperature conducting part, and the temperature conducting part is used for conducting the gas temperature in the unit air bag body;

the heating massage system comprises an air pressure source device, a control module and an identification device;

the air pressure source device is respectively connected with the unit air pressure distributor and is used for providing set air pressure for the unit air pressure distributor; the unit air pressure distributor performs air pressure distribution on the target unit air sac body connected with the unit air pressure distributor, the unit air pressure distributor sets air pressure or zero air pressure for the target unit air sac body, when the set air pressure is distributed, the target unit air sac body expands, and when the zero air pressure is distributed, the target unit air sac body does not expand;

the identification device is used for acquiring an occupied area of a user lying on the top surface of the bearing base cushion, the control module is used for acquiring a unit air bag body needing to be controlled according to the occupied area, the unit air bag body is marked as a target unit air bag body, a unit graphene power generation heat film corresponding to the target unit air bag body is marked as a target unit graphene power generation heat film, and a unit air pressure distributor corresponding to the target unit air bag body is marked as a target unit air pressure distributor;

the control module is used for controlling the target unit air pressure distributor to carry out air pressure distribution on the target unit air bag body connected with the target unit air pressure distributor so as to control the expansion frequency of the target unit air bag body;

the control module is used for controlling the gas temperature in the target unit air bag body by adjusting the heating temperature of the target unit graphene power generation hot film.

2. The multifunctional graphene mattress according to claim 1, further comprising a frequency input module, wherein the frequency input module is connected to the control module, and is configured to receive a target expansion frequency input by a user;

the frequency input module updates the target expansion frequency input by a user, the control module acquires the target expansion frequency from the frequency input module when confirming that the target expansion frequency input by the user is updated, and the control module controls the target unit air pressure distributor to perform air pressure distribution on the target unit air bag body connected with the target unit air bag distributor so as to control the expansion frequency of the target unit air bag body to be adjusted to the target expansion frequency.

3. The multifunctional graphene mattress according to claim 1, further comprising a temperature input module, wherein the temperature input module is connected with the control module, and is used for receiving a target temperature input by a user;

the temperature input module updates the target temperature input by a user, the control module acquires the target temperature from the temperature input module when confirming that the target temperature input by the user is updated, and the control module controls the target unit graphene power generation thermal film so that the gas temperature in the target unit gas bag body reaches the target temperature.

4. The multifunctional graphene mattress according to claim 1, wherein the identification device is configured to obtain an occupied area of a user lying on the top surface of the load-bearing base pad, and specifically comprises: the recognition device shoots a top view of a user lying on the bearing top surface of the bearing base pad, extracts the outline of the user according to the top view, and the area surrounded by the outline on the top surface is an occupied area.

5. The multifunctional graphene mattress according to claim 4, wherein the control module is configured to obtain the unit airbag body to be controlled according to the occupied area, and specifically comprises: the control module establishes a corresponding plane coordinate system by taking the top surface of the bearing base pad as a datum plane, and obtains the whole coordinate range of the occupied area in the plane coordinate system;

and acquiring the coordinate information of each unit airbag body installed in the cavity array in the plane coordinate system, and further screening out all unit airbag bodies of which the coordinate information falls in the whole coordinate range to obtain the unit airbag body which is the unit airbag body required to be controlled.

6. The multifunctional graphene mattress according to claim 1, further comprising a music playing system, wherein the music playing system is configured to obtain a target expansion frequency of the unit air cell, access a cloud music website to obtain a daily recommended menu, and play the last time to randomly select a song from the daily recommended menu according to a number value of the target expansion frequency as a number of randomly selecting songs from the daily recommended menu.

7. The multifunctional graphene mattress according to claim 1, wherein the control module is a control system with a single chip microcomputer as a core.

8. The multifunctional graphene mattress according to claim 7, wherein the single chip microcomputer comprises an STM32 single chip microcomputer.

9. The multifunctional graphene mattress according to claim 1, further comprising an intelligent sleep monitoring system, wherein the intelligent sleep monitoring system is configured to monitor in real time and comprises: the heart rate value of the user lying on the bearing base pad, the breathing rate of the user lying on the bearing base pad, the time that the user leaves the bearing base pad, the duration that the user stays on the bearing base pad and the ambient temperature of the environment where the bearing base pad is located, and will the heart rate value of the user lying on the bearing base pad, the breathing rate of the user lying on the bearing base pad, the time that the user leaves the bearing base pad, the duration that the user stays on the bearing base pad and the ambient temperature of the environment where the bearing base pad is located are uploaded to the remote server in real time.

Images