阅读说明：本技术 具有睡眠监测功能的石墨烯智能温控床垫 (Graphene intelligent temperature control mattress with sleep monitoring function ) 是由 陈建业 于 2021-08-03 设计创作，主要内容包括：本发明公开了具有睡眠监测功能的石墨烯智能温控床垫,包括：石墨烯分区加温系统,用于通过将石墨烯加温片分区布置在石墨烯智能温控床垫的表面,对床垫进行分区加温；睡眠状态监测系统,用于通过石墨烯分布式压力测量监测身体位置、状态,分析预测睡眠状态的身体姿态；石墨烯控制及测温系统,用于将电网高电压转换为电源低电压供电,对石墨烯加温模块的加温启停进行控制,通过石墨烯测温系统进行测温；石墨烯综合智能温控系统,用于根据睡眠状态综合监测数据,进行睡眠状态综合监测数据智能处理,并对床垫进行综合智能温度控制。(The invention discloses a graphene intelligent temperature control mattress with a sleep monitoring function, which comprises: the graphene partitioned heating system is used for partitioning and arranging the graphene heating sheets on the surface of the graphene intelligent temperature control mattress to perform partitioned heating on the mattress; the sleep state monitoring system is used for monitoring the body position and state through graphene distributed pressure measurement and analyzing and predicting the body posture of the sleep state; the graphene control and temperature measurement system is used for converting the high voltage of the power grid into low voltage power supply, controlling the heating start and stop of the graphene heating module, and measuring the temperature through the graphene temperature measurement system; the graphene comprehensive intelligent temperature control system is used for intelligently processing the sleep state comprehensive monitoring data according to the sleep state comprehensive monitoring data and comprehensively and intelligently controlling the temperature of the mattress.)

1. Graphite alkene intelligence control by temperature change mattress with sleep monitor function, its characterized in that includes:

the graphene partitioned heating system is used for partitioning and arranging the graphene heating sheets on the surface of the graphene intelligent temperature control mattress to perform partitioned heating on the mattress;

the sleep state monitoring system is used for monitoring the body position and state through graphene distributed pressure measurement and analyzing and predicting the body posture of the sleep state;

the graphene control and temperature measurement system is used for converting the high voltage of the power grid into low voltage power supply, controlling the heating start and stop of the graphene heating module, and measuring the temperature through the graphene temperature measurement system;

the graphene comprehensive intelligent temperature control system is used for intelligently processing the sleep state comprehensive monitoring data according to the sleep state comprehensive monitoring data and comprehensively and intelligently controlling the temperature of the mattress.

2. The graphene intelligent temperature-controlled mattress with sleep monitoring function according to claim 1, wherein the graphene partition warming system comprises:

the graphene heating module is used for heating through a graphene heating membrane to form a stable graphene heating area;

the electric connection layer module is used for electrically connecting the graphene heating module through the electric conductor layer;

the graphene partitioning module is used for partitioning the graphene heating module on the surface of the graphene intelligent temperature control mattress to form graphene partitions capable of being heated respectively;

the surface protection module is used for isolating and protecting the mattress and the body contact layer by arranging a surface protection layer on the surface of the graphene partition module of the graphene intelligent temperature control mattress;

the reflection bottom layer module is used for reflecting the heat radiation generated by the graphene heating module to generate a dual heat radiation effect;

the transmission top layer module is used for reflecting the heat radiation generated by the graphene heating module and the heat radiation of the reflection type bottom layer module and transmitting the heat radiation to the body of the sleeping person; transmission-type top layer module still is used for when external environment temperature is high, graphite alkene heats the module and does not heat, heats the module with the graphite alkene that human thermal radiation transmission gave off the non-state of heating to distribute away through the heat conduction of graphite alkene material, along with ambient temperature's rising, carry out passive adaptability and adjust the mattress and absorb the thermal radiation that gives off human unnecessary temperature with higher speed, and cooperate with the temperature control of graphite alkene subregion system of heating.

3. The graphene intelligent temperature-controlled mattress with sleep monitoring function according to claim 1, wherein the sleep state monitoring system comprises:

the graphene distributed pressure measurement module is used for uniformly distributing the graphene pressure sensors on the upper surface of the graphene intelligent temperature control mattress and detecting the pressure position and pressure change on the surface of the mattress;

the pressure threshold value setting module is used for setting a pressure threshold value of the pressure action heating control module;

the sleep posture analysis module is used for obtaining the position data analysis of the body in the sleep state according to the pressure position and pressure change of the mattress;

and the sleep posture prediction module is used for intelligently predicting the position of the body to be reversed through the analysis of the position data of the body during sleep so as to obtain the predicted position data of the body in the sleep state.

4. The graphene intelligent temperature controlled mattress with sleep monitoring function according to claim 3,

the graphene distributed pressure measurement module comprises:

the graphene pressure sensor distribution unit is used for enabling the graphene pressure sensors to be distributed below the upper surface textile material of the mattress in an equal density mode according to the area of the mattress, and the pressure distribution of the partitions of the graphene partition heating system is obtained among the partitions of the graphene partition heating system;

the graphene pressure sensor measuring unit is used for measuring the pressure value of the graphene pressure sensor distribution unit through the graphene pressure sensor;

the graphene pressure sensor control unit is used for controlling the dormancy and the startup of the graphene pressure sensor, and controlling the graphene pressure sensor to enter the dormancy when the pressure value is in the pressure state stable time and exceeds a set pressure state stable time value; the pressure steady state, comprising: a zero pressure state, a body part pressure state, a full-coverage article pressure state and a local article placing pressure state;

the graphene pressure sensor signal unit is used for transmitting a pressure value signal measured by the graphene pressure sensor measuring unit and transmitting a control signal of the graphene pressure sensor control unit;

the pressure threshold setting module includes:

the pressure value historical data acquisition unit is used for acquiring historical distribution data of the pressure values in the sleep state through historical pressure value data measured by the graphene pressure sensor;

the pressure value historical data processing unit is used for processing the collected pressure value historical distribution data in the sleep state through data processing and removing the pressure value data in the non-sleep state;

pressure value data for a non-sleep state, comprising: arranging the bed pressure data, the transient sitting and lying pressure data and the bed article pressure data;

the pressure value distribution data analysis unit is used for analyzing the historical distribution data of the pressure values in the sleep state to obtain a pressure value distribution data analysis area diagram so as to count the area positions of the pressure value distribution centralization and distribution dispersion;

a pressure value threshold value operation unit for calculating the average pressure value distribution according to the pressure value distribution data analysis region bitmap obtained by the pressure value distribution data analysis unit, and setting the average pressure value distribution as a reference pressure value threshold value;

and the threshold value setting unit is used for setting the reference pressure value threshold values as corresponding reference pressure value threshold values corresponding to the weight and the height of a user of the mattress respectively.

5. The graphene intelligent temperature-controlled mattress with sleep monitoring function according to claim 3, wherein the sleep posture analysis module comprises:

the sleep state real-time pressure value acquisition unit is used for acquiring a sleep state real-time pressure value of the mattress;

the real-time pressure value and pressure threshold value data comparison unit is used for comparing the acquired real-time pressure value of the sleep state of the mattress with the pressure threshold value data;

the body posture analysis unit is used for analyzing and obtaining the body posture in the sleeping state according to the comparison result of the real-time pressure value and pressure threshold data comparison unit;

a sleep state body posture comprising: a lying posture, a left side lying posture, a right side lying posture and a prone posture;

and the body posture time recording unit is used for recording the time kept by the body posture in the sleeping state and storing the record.

6. The graphene intelligent temperature controlled mattress with sleep monitoring function according to claim 3, wherein the sleep posture prediction module comprises:

the sleep posture statistical unit is used for carrying out sleep posture data statistics according to the sleep posture analysis data obtained by the analysis of the sleep posture analysis module to obtain sleep posture statistical data;

the sleep position statistical unit is used for performing sleep position data statistics according to the sleep position analysis data obtained by the analysis of the sleep posture analysis module to obtain sleep position statistical data;

the sleep posture position time counting unit is used for respectively counting the time kept by various sleep postures and the time kept by various sleep positions to obtain sleep posture position time counting data;

and the posture position prediction calculation unit is used for establishing a posture position prediction calculation model according to the sleep posture statistical data, the sleep position statistical data and the sleep posture position time statistical data so as to predict the sleep posture and the sleep position and establish sleep posture position prediction data.

7. The graphene intelligent temperature control mattress with sleep monitoring function according to claim 1, wherein the graphene control and temperature measurement system comprises:

the graphene power supply electrode distribution module is used for providing power supply for a low-voltage safety power supply and carrying out distribution and partition correspondence on the graphene power supply electrodes;

the heating start-stop control module is used for starting and stopping the heating electrode of the graphene electrode bonding module;

the graphene temperature measurement module is used for monitoring the body temperature of the sleep state through the graphene temperature measurement system to obtain body temperature monitoring data, and monitoring the heating temperature of the graphene to obtain heating monitoring data.

8. The graphene intelligent temperature-controlled mattress with sleep monitoring function according to claim 7, wherein the graphene power supply electrode distribution module comprises:

the power grid voltage transformation unit is used for transforming high voltage of a power grid which can cause damage to a human body into low voltage which is safe to the human body through a transformer;

the low-voltage power supply unit is used for supplying power to the whole intelligent temperature control mattress system through the power grid voltage transformation unit;

the graphene power supply electrode distribution unit is used for distributing the graphene power supply electrodes in corresponding areas of the graphene partition heating system and corresponding the graphene power supply electrode distribution and the graphene partitions one by one; and in the heating control process, starting the graphene power supply electrode corresponding heating graphene partition heating system.

9. The graphene intelligent temperature control mattress with sleep monitoring function according to claim 7,

the start-stop control module heats and includes:

the start-stop control action unit is used for receiving a heating start-stop signal and starting and stopping heating of the corresponding area of the graphene partition heating system;

the start-stop signal transmission unit is used for transmitting a heating start signal and a heating stop signal of the start-stop control action unit;

one end of the heating current conduction unit is connected with the graphene electrode connection unit, and the other end of the heating current conduction unit is connected with the start-stop control action unit;

and the graphene electrode connecting unit is used for connecting the power supply electrode and the heating current conducting unit.

The graphene temperature measurement module comprises:

the mattress surface temperature measurement dot array unit is used for carrying out array arrangement on the mattress surface sensors according to temperature measurement points, the lower layer of the array carries out contact type measurement and monitoring on the heating temperature of a graphene subarea heating system of the mattress, and the upper layer of the array carries out non-contact type induction measurement on the environment temperature and the human body surface temperature of the mattress;

the graphene temperature measurement sensing unit is used for measuring temperature through the graphene temperature measurement sensor;

the temperature measurement signal transmission unit is used for transmitting the temperature measurement signal of the graphene temperature measurement sensing unit;

the array area temperature analysis unit is used for calculating the contact ratio of state spectrum curves between a temperature measuring layer of the graphene temperature measuring sensor and the graphene temperature heating layer, and the calculation formula is as follows:

wherein, C₁₂Is the degree of coincidence of the spectral curves between layers, gamma₁(t) is the carbon atom velocity, gamma, of the temperature measuring layer of the graphene temperature measuring sensor at the t moment₁(0) The carbon atom speed at the initial moment of a temperature measuring layer of the graphene temperature measuring sensor is shown, exp represents an exponential formula with e as the base, and-i is an imaginary part;is the frequency, tau is the interval between lamination layers, gamma₂(t) is the carbon atom velocity, gamma, at time t of the graphene heating layer₂(0) The carbon atom velocity at the initial moment of the graphene heating layer; c₁₂The value is increased, the coincidence degree of the spectral curve is increased, and the interlayer thermal conductivity is increased; according to the measured value of the temperature measuring layer of the graphene temperature measuring sensor, the coincidence degree of a spectrum curve between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer is calculated, the thermal conductivity between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer is analyzed, the actual heating temperature of the graphene heating layer is obtained through analysis, and the heating temperature is adjusted through analysis according to the surface temperature of a human body in a sleeping state and the ambient temperature in the sleeping state;

graphite alkene temperature measurement sensing unit includes: the capacitor comprises positive and negative electrode micro-interval capacitor plates, an inter-plate capacitor cavity and an inter-plate capacitor graphene filling material; the positive and negative micro-interval capacitor plates are used for forming positive and negative charge polar plates of the temperature measuring point temperature measuring sensor; the inter-plate capacitor cavity is used for spacing the inter-plate capacitor graphene filling material; the graphene composite filling material for the inter-plate capacitor is used for carrying out graphene composite filling in the space area of the inter-plate capacitor cavity.

10. The graphene intelligent temperature control mattress with sleep monitoring function according to claim 1, wherein the graphene integrated intelligent temperature control system comprises:

the comprehensive data acquisition module is used for acquiring various monitoring data of the sleep state through the data transmission acquisition system of each sleep state monitoring system to obtain the comprehensive sleep state monitoring data;

sleep state integrated monitoring data, including: the body temperature monitoring system comprises data of the position of a body in a sleeping state, data of the pressure of the position of the body, data of the body prediction position in the sleeping state and data of body temperature monitoring;

the control signal transmission module is used for transmitting the intelligent comprehensive temperature control information obtained by the comprehensive data intelligent processing center module to the graphene subarea heating system;

the comprehensive data intelligent processing module is used for intelligently processing the sleep state comprehensive monitoring data acquired by the comprehensive data acquisition module through the intelligent processing center to acquire intelligent comprehensive temperature control information; intelligent integrated temperature control information, comprising: heating information is carried out on the position where the body is located, pre-heating information is carried out on the predicted position of the body, body temperature monitoring and adjusting heating temperature information is controlled, and comprehensive intelligent temperature control information of the mattress is obtained; through intelligent comprehensive temperature control information, comprehensive intelligent temperature control of the graphene intelligent temperature control mattress is achieved.

Technical Field

The invention relates to the field of graphene intelligent temperature control, in particular to a graphene intelligent temperature control mattress with a sleep monitoring function.

Background

The graphene has excellent technical properties such as electrical property, mechanical property, chemical property, heat conductivity and the like, has very advanced technical advantages in the field of modern science and technology, and simultaneously has a plurality of key technical characteristics which are very needed in modern scientific and technological research; the sleep monitoring function is a very important frontier technology in the technical field of mattress innovation; the application of graphene and related systems, devices, sensors and the like to sleep monitoring and intelligent temperature control of the mattress is a technical scheme with innovative significance; the existing mattress can only be heated integrally, but cannot be heated locally and regionally, and the integrally heated mattress can cause a lot of waste of heat in a heating area; the existing mattress does not have the technology of sleep state monitoring, sleep posture prediction and the like, generally only can be used for simple fixed temperature setting for temperature control, and cannot perform comprehensive intelligent processing and comprehensive intelligent temperature control according to sleep state monitoring, sleep posture prediction, sleep state body temperature monitoring, environment monitoring and heating temperature; therefore, it is necessary to provide a graphene smart temperature controlled mattress with a sleep monitoring function to at least partially solve the problems in the prior art.

Disclosure of Invention

In this summary, concepts in a simplified form are introduced that are further described in the detailed description. This summary of the invention is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.

In order to at least partially solve the above problems, the present invention provides a graphene intelligent temperature control mattress with a sleep monitoring function, including:

the graphene partitioned heating system is used for partitioning and arranging the graphene heating sheets on the surface of the graphene intelligent temperature control mattress to perform partitioned heating on the mattress;

the sleep state monitoring system is used for monitoring the body position and state through graphene distributed pressure measurement and analyzing and predicting the body posture of the sleep state;

the graphene control and temperature measurement system is used for converting the high voltage of the power grid into low voltage power supply, controlling the heating start and stop of the graphene heating module, and measuring the temperature through the graphene temperature measurement system;

the graphene comprehensive intelligent temperature control system is used for intelligently processing the sleep state comprehensive monitoring data according to the sleep state comprehensive monitoring data and comprehensively and intelligently controlling the temperature of the mattress.

Preferably, the graphene zoned warming system includes:

the graphene heating module is used for heating through a graphene heating membrane to form a stable graphene heating area;

the electric connection layer module is used for electrically connecting the graphene heating module through the electric conductor layer;

the graphene partitioning module is used for partitioning the graphene heating module on the surface of the graphene intelligent temperature control mattress to form graphene partitions capable of being heated respectively;

the surface protection module is used for isolating and protecting the mattress and the body contact layer by arranging a surface protection layer on the surface of the graphene partition module of the graphene intelligent temperature control mattress;

the reflection bottom layer module is used for reflecting the heat radiation generated by the graphene heating module to generate a dual heat radiation effect;

the transmission top layer module is used for reflecting the heat radiation generated by the graphene heating module and the heat radiation of the reflection type bottom layer module and transmitting the heat radiation to the body of the sleeping person; transmission-type top layer module still is used for when external environment temperature is high, graphite alkene heats the module and does not heat, heats the module with the graphite alkene that human thermal radiation transmission gave off the non-state of heating to distribute away through the heat conduction of graphite alkene material, along with ambient temperature's rising, carry out passive adaptability and adjust the mattress and absorb the thermal radiation that gives off human unnecessary temperature with higher speed, and cooperate with the temperature control of graphite alkene subregion system of heating.

Preferably, the sleep state monitoring system includes:

the graphene distributed pressure measurement module is used for uniformly distributing the graphene pressure sensors on the upper surface of the graphene intelligent temperature control mattress and detecting the pressure position and pressure change on the surface of the mattress;

the pressure threshold value setting module is used for setting a pressure threshold value of the pressure action heating control module;

the sleep posture analysis module is used for obtaining the position data analysis of the body in the sleep state according to the pressure position and pressure change of the mattress;

and the sleep posture prediction module is used for intelligently predicting the position of the body to be reversed through the analysis of the position data of the body during sleep so as to obtain the predicted position data of the body in the sleep state.

Preferably, the graphene distributed pressure measurement module includes:

the graphene pressure sensor distribution unit is used for enabling the graphene pressure sensors to be distributed below the upper surface textile material of the mattress in an equal density mode according to the area of the mattress, and the pressure distribution of the partitions of the graphene partition heating system is obtained among the partitions of the graphene partition heating system;

the graphene pressure sensor measuring unit is used for measuring the pressure value of the graphene pressure sensor distribution unit through the graphene pressure sensor;

the graphene pressure sensor control unit is used for controlling the dormancy and the startup of the graphene pressure sensor, and controlling the graphene pressure sensor to enter the dormancy when the pressure value is in the pressure state stable time and exceeds a set pressure state stable time value; the pressure steady state, comprising: a zero pressure state, a body part pressure state, a full-coverage article pressure state and a local article placing pressure state;

the graphene pressure sensor signal unit is used for transmitting a pressure value signal measured by the graphene pressure sensor measuring unit and transmitting a control signal of the graphene pressure sensor control unit;

the pressure threshold setting module includes:

the pressure value historical data acquisition unit is used for acquiring historical distribution data of the pressure values in the sleep state through historical pressure value data measured by the graphene pressure sensor;

the pressure value historical data processing unit is used for processing the collected pressure value historical distribution data in the sleep state through data processing and removing the pressure value data in the non-sleep state;

pressure value data for a non-sleep state, comprising: arranging the bed pressure data, the transient sitting and lying pressure data and the bed article pressure data;

the pressure value distribution data analysis unit is used for analyzing the historical distribution data of the pressure values in the sleep state to obtain a pressure value distribution data analysis area diagram so as to count the area positions of the pressure value distribution centralization and distribution dispersion;

a pressure value threshold value operation unit for calculating the average pressure value distribution according to the pressure value distribution data analysis region bitmap obtained by the pressure value distribution data analysis unit, and setting the average pressure value distribution as a reference pressure value threshold value;

and the threshold value setting unit is used for setting the reference pressure value threshold values as corresponding reference pressure value threshold values corresponding to the weight and the height of a user of the mattress respectively.

Preferably, the sleep posture analysis module includes:

the sleep state real-time pressure value acquisition unit is used for acquiring a sleep state real-time pressure value of the mattress;

the real-time pressure value and pressure threshold value data comparison unit is used for comparing the acquired real-time pressure value of the sleep state of the mattress with the pressure threshold value data;

the body posture analysis unit is used for analyzing and obtaining the body posture in the sleeping state according to the comparison result of the real-time pressure value and pressure threshold data comparison unit;

a sleep state body posture comprising: a lying posture, a left side lying posture, a right side lying posture and a prone posture;

and the body posture time recording unit is used for recording the time kept by the body posture in the sleeping state and storing the record.

Preferably, the sleep posture prediction module includes:

the sleep posture statistical unit is used for carrying out sleep posture data statistics according to the sleep posture analysis data obtained by the analysis of the sleep posture analysis module to obtain sleep posture statistical data;

the sleep position statistical unit is used for performing sleep position data statistics according to the sleep position analysis data obtained by the analysis of the sleep posture analysis module to obtain sleep position statistical data;

the sleep posture position time counting unit is used for respectively counting the time kept by various sleep postures and the time kept by various sleep positions to obtain sleep posture position time counting data;

and the posture position prediction calculation unit is used for establishing a posture position prediction calculation model according to the sleep posture statistical data, the sleep position statistical data and the sleep posture position time statistical data so as to predict the sleep posture and the sleep position and establish sleep posture position prediction data.

Preferably, the graphene control and temperature measurement system includes:

the graphene power supply electrode distribution module is used for providing power supply for a low-voltage safety power supply and carrying out distribution and partition correspondence on the graphene power supply electrodes;

the heating start-stop control module is used for starting and stopping the heating electrode of the graphene electrode bonding module;

the graphene temperature measurement module is used for monitoring the body temperature of the sleep state through the graphene temperature measurement system to obtain body temperature monitoring data, and monitoring the heating temperature of the graphene to obtain heating monitoring data.

Preferably, the graphene power supply electrode distribution module includes:

the power grid voltage transformation unit is used for transforming high voltage of a power grid which can cause damage to a human body into low voltage which is safe to the human body through a transformer;

the low-voltage power supply unit is used for supplying power to the whole intelligent temperature control mattress system through the power grid voltage transformation unit;

the graphene power supply electrode distribution unit is used for distributing the graphene power supply electrodes in corresponding areas of the graphene partition heating system and corresponding the graphene power supply electrode distribution and the graphene partitions one by one; and in the heating control process, starting the graphene power supply electrode corresponding heating graphene partition heating system.

Preferably, the warming start-stop control module includes:

the start-stop control action unit is used for receiving a heating start-stop signal and starting and stopping heating of the corresponding area of the graphene partition heating system;

the start-stop signal transmission unit is used for transmitting a heating start signal and a heating stop signal of the start-stop control action unit;

one end of the heating current conduction unit is connected with the graphene electrode connection unit, and the other end of the heating current conduction unit is connected with the start-stop control action unit;

and the graphene electrode connecting unit is used for connecting the power supply electrode and the heating current conducting unit.

The graphene temperature measurement module comprises:

the mattress surface temperature measurement dot array unit is used for carrying out array arrangement on the mattress surface sensors according to temperature measurement points, the lower layer of the array carries out contact type measurement and monitoring on the heating temperature of a graphene subarea heating system of the mattress, and the upper layer of the array carries out non-contact type induction measurement on the environment temperature and the human body surface temperature of the mattress;

the graphene temperature measurement sensing unit is used for measuring temperature through the graphene temperature measurement sensor;

the temperature measurement signal transmission unit is used for transmitting the temperature measurement signal of the graphene temperature measurement sensing unit;

the array area temperature analysis unit is used for calculating the contact ratio of state spectrum curves between a temperature measuring layer of the graphene temperature measuring sensor and the graphene temperature heating layer, and the calculation formula is as follows:

wherein, C₁₂Is the degree of coincidence of the spectral curves between layers, gamma₁(t) is the carbon atom velocity, gamma, of the temperature measuring layer of the graphene temperature measuring sensor at the t moment₁(0) The carbon atom speed at the initial moment of a temperature measuring layer of the graphene temperature measuring sensor is shown, exp represents an exponential formula with e as the base, and-i is an imaginary part;is the frequency, tau is the interval between lamination layers, gamma₂(t) is the carbon atom velocity, gamma, at time t of the graphene heating layer₂(0) The carbon atom velocity at the initial moment of the graphene heating layer; c₁₂The value is increased, the coincidence degree of the spectral curve is increased, and the interlayer thermal conductivity is increased; according to the measured value of the temperature measuring layer of the graphene temperature measuring sensor, the coincidence degree of a spectrum curve between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer is calculated, the thermal conductivity between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer is analyzed, the actual heating temperature of the graphene heating layer is obtained through analysis, and the heating temperature is adjusted through analysis according to the surface temperature of a human body in a sleeping state and the ambient temperature in the sleeping state;

graphite alkene temperature measurement sensing unit includes: the capacitor comprises positive and negative electrode micro-interval capacitor plates, an inter-plate capacitor cavity and an inter-plate capacitor graphene filling material; the positive and negative micro-interval capacitor plates are used for forming positive and negative charge polar plates of the temperature measuring point temperature measuring sensor; the inter-plate capacitor cavity is used for spacing the inter-plate capacitor graphene filling material; the graphene composite filling material for the inter-plate capacitor is used for carrying out graphene composite filling in the space area of the inter-plate capacitor cavity.

Preferably, the graphene integrated intelligent temperature control system includes:

the comprehensive data acquisition module is used for acquiring various monitoring data of the sleep state through the data transmission acquisition system of each sleep state monitoring system to obtain the comprehensive sleep state monitoring data;

sleep state integrated monitoring data, including: the body temperature monitoring system comprises data of the position of a body in a sleeping state, data of the pressure of the position of the body, data of the body prediction position in the sleeping state and data of body temperature monitoring;

the control signal transmission module is used for transmitting the intelligent comprehensive temperature control information obtained by the comprehensive data intelligent processing center module to the graphene subarea heating system;

the comprehensive data intelligent processing module is used for intelligently processing the sleep state comprehensive monitoring data acquired by the comprehensive data acquisition module through the intelligent processing center to acquire intelligent comprehensive temperature control information; intelligent integrated temperature control information, comprising: heating information is carried out on the position where the body is located, pre-heating information is carried out on the predicted position of the body, body temperature monitoring and adjusting heating temperature information is controlled, and comprehensive intelligent temperature control information of the mattress is obtained; through intelligent comprehensive temperature control information, comprehensive intelligent temperature control of the graphene intelligent temperature control mattress is achieved.

Compared with the prior art, the invention at least comprises the following beneficial effects:

the graphene heating sheet is arranged on the surface of the graphene intelligent temperature control mattress in a partitioned manner, so that the mattress can be heated in a partitioned manner, the energy utilization in the heating process is more efficient, and the heat energy loss of unnecessary heating areas is reduced; the body position and state are monitored through graphene distributed pressure measurement, the body posture of the sleep state can be analyzed and predicted, and the system has the technical advantages of sleep state monitoring and sleep posture prediction; the high voltage of the power grid can be converted into low voltage power supply of a power supply, so that low voltage power supply safe to a human body is provided, and the high voltage leakage of the power grid is prevented from causing damage to the human body; the low-voltage electric heating performance of the graphene is combined, so that the low voltage can have the voltage technical condition required by heating, and a large amount of electric energy can be saved in the heating process; the heating start and stop of the graphene heating module are controlled, temperature is measured through the graphene temperature measuring system, the graphene temperature measuring system is directly adopted, a large number of other temperature measuring elements do not need to be additionally arranged, and the thermal performance of the graphene material can be directly used as a temperature measuring material source of the temperature measuring system; the technical performance advantages of the graphene material such as electrical performance, mechanical performance, thermal performance and the like can be more fully exerted; according to the comprehensive monitoring data of the sleep state, the comprehensive monitoring data of the sleep state can be intelligently processed according to the comprehensive data information such as the sleep state monitoring, the sleep posture prediction, the sleep state body temperature monitoring, the environment monitoring, the heating temperature and the like through the comprehensive intelligent system, and the comprehensive intelligent temperature control can be carried out on the mattress.

Other advantages, objects, and features of the graphene intelligent temperature controlled mattress with sleep monitoring function according to the present invention will be in part apparent from the following description and in part will become apparent to those skilled in the art upon examination of the following or may be learned from practice of the present invention.

Drawings

The accompanying drawings, which 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 description serve to explain the principles of the invention and not to limit the invention. In the drawings:

fig. 1 is a system diagram of a graphene intelligent temperature control mattress module with a sleep monitoring function according to the present invention.

Fig. 2 is a connection diagram of the graphene intelligent temperature control mattress system with the sleep monitoring function.

Fig. 3 is a system diagram of a sleep state monitoring system of the graphene intelligent temperature control mattress with the sleep monitoring function.

Fig. 4 is a system diagram of graphene control and temperature measurement system of the graphene intelligent temperature control mattress with sleep monitoring function according to the invention.

Detailed Description

The present invention is further described in detail below with reference to the drawings and examples so that those skilled in the art can practice the invention with reference to the description.

As shown in fig. 1, 2, 3 and 4, the present invention provides a graphene intelligent temperature control mattress with a sleep monitoring function, comprising:

the graphene partitioned heating system is used for partitioning and arranging the graphene heating sheets on the surface of the graphene intelligent temperature control mattress to perform partitioned heating on the mattress;

the sleep state monitoring system is used for monitoring the body position and state through graphene distributed pressure measurement and analyzing and predicting the body posture of the sleep state;

the graphene control and temperature measurement system is used for converting the high voltage of the power grid into low voltage power supply, controlling the heating start and stop of the graphene heating module, and measuring the temperature through the graphene temperature measurement system;

the graphene comprehensive intelligent temperature control system is used for intelligently processing the sleep state comprehensive monitoring data according to the sleep state comprehensive monitoring data and comprehensively and intelligently controlling the temperature of the mattress.

The working principle of the technical scheme is as follows: the method comprises the following steps that a graphene heating sheet is arranged on the surface of a graphene intelligent temperature control mattress in a partitioning mode, and the mattress is heated in a partitioning mode; monitoring the body position and state through graphene distributed pressure measurement, and analyzing and predicting the body posture of the sleeping state; converting the high voltage of the power grid into low voltage of a power supply for power supply, controlling the heating start and stop of the graphene heating module, and measuring the temperature through a graphene temperature measuring system; and intelligently processing the sleep state comprehensive monitoring data according to the sleep state comprehensive monitoring data, and carrying out comprehensive intelligent temperature control on the mattress.

The beneficial effects of the above technical scheme are that: the graphene heating sheet is arranged on the surface of the graphene intelligent temperature control mattress in a partitioned manner, so that the mattress can be heated in a partitioned manner, the energy utilization in the heating process is more efficient, and the heat energy loss of unnecessary heating areas is reduced; the body position and state are monitored through graphene distributed pressure measurement, the body posture of the sleep state can be analyzed and predicted, and the system has the technical advantages of sleep state monitoring and sleep posture prediction; the high voltage of the power grid can be converted into low voltage power supply of a power supply, so that low voltage power supply safe to a human body is provided, and the high voltage leakage of the power grid is prevented from causing damage to the human body; the low-voltage electric heating performance of the graphene is combined, so that the low voltage can have the voltage technical condition required by heating, and a large amount of electric energy can be saved in the heating process; the heating start and stop of the graphene heating module are controlled, temperature is measured through the graphene temperature measuring system, the graphene temperature measuring system is directly adopted, a large number of other temperature measuring elements do not need to be additionally arranged, and the thermal performance of the graphene material can be directly used as a temperature measuring material source of the temperature measuring system; the technical performance advantages of the graphene material such as electrical performance, mechanical performance, thermal performance and the like can be more fully exerted; according to the comprehensive monitoring data of the sleep state, the comprehensive monitoring data of the sleep state can be intelligently processed according to the comprehensive data information such as the sleep state monitoring, the sleep posture prediction, the sleep state body temperature monitoring, the environment monitoring, the heating temperature and the like through the comprehensive intelligent system, and the comprehensive intelligent temperature control can be carried out on the mattress.

In one embodiment, the graphene zoned warming system includes:

the graphene heating module is used for heating through a graphene heating membrane to form a stable graphene heating area;

the electric connection layer module is used for electrically connecting the graphene heating module through the electric conductor layer;

the graphene partitioning module is used for partitioning the graphene heating module on the surface of the graphene intelligent temperature control mattress to form graphene partitions capable of being heated respectively;

the surface protection module is used for isolating and protecting the mattress and the body contact layer by arranging a surface protection layer on the surface of the graphene partition module of the graphene intelligent temperature control mattress;

the reflection bottom layer module is used for reflecting the heat radiation generated by the graphene heating module to generate a dual heat radiation effect;

the transmission top layer module is used for reflecting the heat radiation generated by the graphene heating module and the heat radiation of the reflection type bottom layer module and transmitting the heat radiation to the body of the sleeping person; transmission-type top layer module still is used for when external environment temperature is high, graphite alkene heats the module and does not heat, heats the module with the graphite alkene that human thermal radiation transmission gave off the non-state of heating to distribute away through the heat conduction of graphite alkene material, along with ambient temperature's rising, carry out passive adaptability and adjust the mattress and absorb the thermal radiation that gives off human unnecessary temperature with higher speed, and cooperate with the temperature control of graphite alkene subregion system of heating.

The working principle of the technical scheme is as follows: heating through a graphene heating membrane to form a stable graphene heating area; the graphene heating modules are electrically connected through the electric conductor layer, all heating areas can be independently heated, and the area wiring adopts a gathering branch structure; arranging the graphene heating modules on the surface of the graphene intelligent temperature control mattress in a partitioning manner to form graphene partitions capable of being heated respectively; the surface protection layer is arranged on the surface of the graphene partition module of the graphene intelligent temperature control mattress and is used for isolating and protecting the mattress and the body contact layer; reflecting the heat radiation generated by the graphene heating module to generate a dual heat radiation effect; the heat radiation generated by the graphene heating module and the heat radiation of the reflective bottom layer module are reflected and transmitted to the body of the sleeping person; transmission-type top layer module still is used for when external environment temperature is high, graphite alkene heats the module and does not heat, heats the module with the graphite alkene that human thermal radiation transmission gave off the non-state of heating to distribute away through the heat conduction of graphite alkene material, along with ambient temperature's rising, carry out passive adaptability and adjust the mattress and absorb the thermal radiation that gives off human unnecessary temperature with higher speed, and cooperate with the temperature control of graphite alkene subregion system of heating.

The beneficial effects of the above technical scheme are that: the graphene heating membrane can be used for heating, a stable graphene heating area can be formed, and the graphene heating module is electrically connected through the electric conductor layer; the graphene heating modules can be arranged on the surface of the graphene intelligent temperature control mattress in a partitioned manner to form graphene partitions capable of being heated respectively; the surface protection layer is arranged on the surface of the graphene partition module of the graphene intelligent temperature control mattress, so that the mattress and the body contact layer can be isolated and protected; the heat radiation generated by the graphene heating module is reflected, so that a dual heat radiation effect can be generated; the heat radiation generated by the graphene heating module and the heat radiation of the reflective bottom layer module can be reflected and transmitted to the body of a sleeping person, a more beneficial heat energy superposition effect is formed on the body to a certain extent, the heating heat energy loss can be greatly reduced compared with single-sided radiation, and the heat energy utilization efficiency is improved; transmission-type top layer module can also be used for when external environment temperature is high, graphite alkene heats the module and does not heat, heats the module with human heat radiation transmission giving off the graphite alkene of non-heating state to heat conduction through graphite alkene material distributes away, along with ambient temperature's rising, can carry out passive adaptability and adjust the mattress and absorb the heat radiation that gives off human unnecessary temperature with higher speed, and can cooperate with the temperature control of graphite alkene subregion system of heating.

In one embodiment, the sleep state monitoring system comprises:

the graphene distributed pressure measurement module is used for uniformly distributing the graphene pressure sensors on the upper surface of the graphene intelligent temperature control mattress and detecting the pressure position and pressure change on the surface of the mattress;

the pressure threshold value setting module is used for setting a pressure threshold value of the pressure action heating control module;

the sleep posture analysis module is used for obtaining the position data analysis of the body in the sleep state according to the pressure position and pressure change of the mattress;

and the sleep posture prediction module is used for intelligently predicting the position of the body to be reversed through the analysis of the position data of the body during sleep so as to obtain the predicted position data of the body in the sleep state.

The working principle of the technical scheme is as follows: the graphene pressure sensors are uniformly distributed on the upper surface of the graphene intelligent temperature control mattress and used for detecting the pressure position and pressure change on the surface of the mattress; the pressure position and the pressure change on the surface of the mattress are jointed, the mean value of the measurement data is calculated, and the pressure threshold value of the pressure action heating control module is set; obtaining the position data analysis of the body in the sleeping state according to the pressure position and pressure change of the mattress; intelligently predicting the position of the body to be reversed by analyzing the data of the position of the body during sleeping to obtain the predicted position data of the body in a sleeping state; the data analysis of the position of the body in the sleeping state can adopt analysis methods such as data comparison analysis and big data analysis.

The beneficial effects of the above technical scheme are that: the graphene pressure sensors are uniformly distributed on the upper surface of the graphene intelligent temperature control mattress, so that the pressure position and pressure change on the surface of the mattress can be detected; the uniform distribution can make the pressure measurement area more accurate; the pressure threshold value of the pressure action heating control module can be set according to the calculated average value of the measurement data; the pressure threshold value can be set to eliminate the pressure generated by other articles on the mattress, so that the mistaken heating is avoided; obtaining the position data analysis of the body in the sleeping state according to the pressure position and pressure change of the mattress; through the analysis of the data of the position of the body during sleeping, the position of the body to be reversed is intelligently predicted, and the predicted position data of the body in a sleeping state can be obtained; the data analysis of the position of the sleeping body can adopt analysis methods such as data comparison analysis and big data analysis, so that the predicted position data of the sleeping body is more fit with the actual position rule.

In one embodiment, the graphene distributed pressure measurement module includes:

the graphene pressure sensor distribution unit is used for enabling the graphene pressure sensors to be distributed below the upper surface textile material of the mattress in an equal density mode according to the area of the mattress, and the pressure distribution of the partitions of the graphene partition heating system is obtained among the partitions of the graphene partition heating system;

the graphene pressure sensor measuring unit is used for measuring the pressure value of the graphene pressure sensor distribution unit through the graphene pressure sensor;

the graphene pressure sensor control unit is used for controlling the dormancy and the startup of the graphene pressure sensor, and controlling the graphene pressure sensor to enter the dormancy when the pressure value is in the pressure state stable time and exceeds a set pressure state stable time value; the pressure steady state, comprising: a zero pressure state, a body part pressure state, a full-coverage article pressure state and a local article placing pressure state;

the graphene pressure sensor signal unit is used for transmitting a pressure value signal measured by the graphene pressure sensor measuring unit and transmitting a control signal of the graphene pressure sensor control unit;

the pressure threshold setting module includes:

the pressure value historical data acquisition unit is used for acquiring historical distribution data of the pressure values in the sleep state through historical pressure value data measured by the graphene pressure sensor;

the pressure value historical data processing unit is used for processing the collected pressure value historical distribution data in the sleep state through data processing and removing the pressure value data in the non-sleep state;

pressure value data for a non-sleep state, comprising: arranging the bed pressure data, the transient sitting and lying pressure data and the bed article pressure data;

the pressure value distribution data analysis unit is used for analyzing the historical distribution data of the pressure values in the sleep state to obtain a pressure value distribution data analysis area diagram so as to count the area positions of the pressure value distribution centralization and distribution dispersion;

a pressure value threshold value operation unit for calculating the average pressure value distribution according to the pressure value distribution data analysis region bitmap obtained by the pressure value distribution data analysis unit, and setting the average pressure value distribution as a reference pressure value threshold value;

and the threshold value setting unit is used for setting the reference pressure value threshold values as corresponding reference pressure value threshold values corresponding to the weight and the height of a user of the mattress respectively.

The working principle of the technical scheme is as follows: the method comprises the following steps of (1) enabling graphene pressure sensors to be distributed below the upper surface textile material of a mattress in an equal density mode according to the area of the mattress, and enabling the graphene pressure sensors to be arranged between partitions of a graphene partition heating system, so that the pressure distribution of the partitions of the graphene partition heating system is obtained; measuring the pressure value of a graphene pressure sensor distribution unit through a graphene pressure sensor; controlling the dormancy and the startup of the graphene pressure sensor, and controlling the graphene pressure sensor to enter the dormancy when the pressure value is in the pressure state stable time and exceeds a set pressure state stable time value; the pressure steady state, comprising: a zero pressure state, a body part pressure state, a full-coverage article pressure state and a local article placing pressure state; transmitting a pressure value signal measured by the graphene pressure sensor measuring unit, and transmitting a control signal of the graphene pressure sensor control unit;

acquiring historical pressure value distribution data of a sleep state through historical pressure value data measured by a graphene pressure sensor; processing the collected pressure value historical distribution data in the sleep state by data processing, and removing the pressure value data in the non-sleep state; pressure value data for a non-sleep state, comprising: the pressure data of the beds, the transient sitting and lying pressure data and the pressure data of bed articles are arranged, and other types of non-sleep state pressure value data can be identified through self-learning of the system; analyzing the historical distribution data of the pressure values in the sleep state to obtain a pressure value distribution data analysis region bitmap, and counting the positions of the regions with centralized and dispersed pressure value distribution; calculating average pressure value distribution according to the pressure value distribution data analysis region bitmap obtained by the pressure value distribution data analysis unit, and setting the average pressure value distribution as a reference pressure value threshold; and setting corresponding reference pressure value thresholds corresponding to the weight and the height of the mattress user respectively according to the reference pressure value thresholds.

The beneficial effects of the above technical scheme are that: the graphene pressure sensors are distributed below the upper surface textile material of the mattress according to the area of the mattress in an equal density mode, and the pressure distribution of the partitions of the graphene partition heating system can be obtained among the partitions of the graphene partition heating system; measuring the pressure value of a graphene pressure sensor distribution unit through a graphene pressure sensor; controlling the dormancy and the startup of the graphene pressure sensor, and controlling the graphene pressure sensor to enter the dormancy when the pressure value is in the pressure state stable time and exceeds a set pressure state stable time value; the pressure steady state, comprising: a zero pressure state, a body part pressure state, a full-coverage article pressure state and a local article placing pressure state; transmitting a pressure value signal measured by the graphene pressure sensor measuring unit, and transmitting a control signal of the graphene pressure sensor control unit;

acquiring historical pressure value distribution data of a sleep state through historical pressure value data measured by a graphene pressure sensor; processing the collected pressure value historical distribution data in the sleep state by data processing, and removing the pressure value data in the non-sleep state; the pressure value data of the non-sleep state can comprise: the pressure data of the beds, the transient sitting and lying pressure data and the pressure data of bed articles are arranged, and other types of non-sleep state pressure value data can be identified through self-learning of the system; analyzing the historical distribution data of the pressure values in the sleep state to obtain a pressure value distribution data analysis region bitmap, and counting the positions of the regions with centralized and dispersed pressure value distribution; calculating average pressure value distribution according to the pressure value distribution data analysis region bitmap obtained by the pressure value distribution data analysis unit, and setting the average pressure value distribution as a reference pressure value threshold; the reference pressure value threshold value can be set to correspond to the weight and the height of a user of the mattress, so that the monitoring of the sleeping state position area of the mattress has wider adaptability.

In one embodiment, the sleep posture analysis module includes:

the sleep state real-time pressure value acquisition unit is used for acquiring a sleep state real-time pressure value of the mattress;

the real-time pressure value and pressure threshold value data comparison unit is used for comparing the acquired real-time pressure value of the sleep state of the mattress with the pressure threshold value data;

the body posture analysis unit is used for analyzing and obtaining the body posture in the sleeping state according to the comparison result of the real-time pressure value and pressure threshold data comparison unit;

a sleep state body posture comprising: a lying posture, a left side lying posture, a right side lying posture and a prone posture;

and the body posture time recording unit is used for recording the time kept by the body posture in the sleeping state and storing the record.

The working principle of the technical scheme is as follows: acquiring a real-time pressure value of the sleep state of the mattress through a pressure value data acquisition unit; comparing the acquired real-time pressure value of the sleep state of the mattress with pressure threshold data through a comparator; analyzing to obtain the body posture in the sleeping state according to the comparison result of the real-time pressure value and pressure threshold data comparison unit; a sleep state body posture comprising: a lying posture, a left side lying posture, a right side lying posture and a prone posture; recording the time of keeping the body posture in the sleeping state, and storing the record; the special sleep state may further be used as a determination of sleep state abnormalities.

The beneficial effects of the above technical scheme are that: by collecting the real-time pressure value of the sleeping state of the mattress, more accurate real-time pressure of the sleeping state can be obtained; the acquired real-time pressure value of the sleeping state of the mattress is compared with the pressure threshold value data, so that whether the real-time pressure value of the sleeping state of the mattress is in the set pressure threshold value range or not can be identified more accurately; the body posture in the sleeping state can be analyzed and obtained through the comparison result of the real-time pressure value and pressure threshold data comparison unit; a sleep state body posture comprising: a lying posture, a left side lying posture, a right side lying posture and a prone posture; different body postures have different pressure values and pressure area characteristics, and most sleep postures can be covered by adopting typical sleep posture analysis; the time for keeping the body posture in the sleeping state can be recorded and the record is stored; some special sleeping postures can also be used as judgment of abnormal sleeping states, and whether some special unexpected situations which do not accord with normal sleeping postures occur in sleeping can be detected in an auxiliary mode.

In one embodiment, the sleep posture prediction module comprises:

the sleep posture statistical unit is used for carrying out sleep posture data statistics according to the sleep posture analysis data obtained by the analysis of the sleep posture analysis module to obtain sleep posture statistical data;

the sleep position statistical unit is used for performing sleep position data statistics according to the sleep position analysis data obtained by the analysis of the sleep posture analysis module to obtain sleep position statistical data;

the sleep posture position time counting unit is used for respectively counting the time kept by various sleep postures and the time kept by various sleep positions to obtain sleep posture position time counting data;

and the posture position prediction calculation unit is used for establishing a posture position prediction calculation model according to the sleep posture statistical data, the sleep position statistical data and the sleep posture position time statistical data so as to predict the sleep posture and the sleep position and establish sleep posture position prediction data.

The working principle of the technical scheme is as follows: according to the sleep posture analysis data obtained by the analysis of the sleep posture analysis module, carrying out sleep posture data statistics to obtain sleep posture statistical data; according to the sleep position analysis data obtained by analyzing the sleep posture analysis module, carrying out sleep position data statistics to obtain sleep position statistical data; respectively counting the time kept by various sleep postures and the time kept by various sleep positions to obtain sleep posture position time statistical data; establishing an attitude position prediction calculation model according to the sleep attitude statistical data, the sleep position statistical data and the sleep attitude position time statistical data so as to predict the sleep attitude and the sleep position and establish sleep attitude position prediction data; some special sleep posture positions can be further used for judging whether the sleep state is abnormal or not, and can be used for assisting in detecting whether some safety conditions, such as falling bed danger, edge accidents and the like, which do not accord with the position of a safe sleep area easily occur or not during sleep.

The beneficial effects of the above technical scheme are that: according to the sleep posture analysis data obtained by the analysis of the sleep posture analysis module, the sleep posture data statistics can be carried out to obtain the sleep posture statistical data; according to the sleep position analysis data obtained by analyzing the sleep posture analysis module, carrying out sleep position data statistics to obtain sleep position statistical data; respectively counting the time kept by various sleep postures and the time kept by various sleep positions to obtain sleep posture position time statistical data; establishing an attitude position prediction calculation model according to the sleep attitude statistical data, the sleep position statistical data and the sleep attitude position time statistical data so as to predict the sleep attitude and the sleep position and establish sleep attitude position prediction data; some special sleep posture positions can be further used as a judgment of whether the sleep state is abnormal or not, and can be used for simultaneously assisting in detecting whether some safety conditions which are not in accordance with the position of a safe sleep area and are easy to fall off the bed, have edge accidents and the like or not, and particularly have a certain protection effect on children and old people.

In one embodiment, the graphene control and temperature measurement system includes:

the graphene power supply electrode distribution module is used for providing power supply for a low-voltage safety power supply and carrying out distribution and partition correspondence on the graphene power supply electrodes;

the heating start-stop control module is used for starting and stopping the heating electrode of the graphene electrode bonding module;

the graphene temperature measurement module is used for monitoring the body temperature of the sleep state through the graphene temperature measurement system to obtain body temperature monitoring data, and monitoring the heating temperature of the graphene to obtain heating monitoring data.

The working principle of the technical scheme is as follows: providing a low-voltage safety power supply through a power supply electrode, and carrying out distribution and partition correspondence on the graphene power supply electrode; the heating electrode is used for starting and stopping the graphene electrode joint module, and the branch node transistor can be used for controlling the on and off of the heating electrode when the heating electrode is started and stopped; the body temperature monitoring system monitors the body temperature in a sleep state to acquire body temperature monitoring data, and monitors the heating temperature of the graphene to acquire heating monitoring data.

The beneficial effects of the above technical scheme are that: the power supply can provide low-voltage safety power supply through the power supply electrode, and the graphene power supply electrode can be distributed and partitioned correspondingly; the heating electrode of the graphene electrode bonding module can be started and stopped; the body temperature in the sleep state is monitored through the graphene temperature measuring system to obtain body temperature monitoring data, and the graphene heating temperature can be monitored to obtain heating monitoring data; preventing the heating temperature from greatly fluctuating or exceeding the proper temperature; when the temperature is too high and exceeds the set temperature, the system temperature is monitored and fed back to the intelligent control system, so that the heating can be stopped, accidents can be avoided, and unnecessary additional heating can be reduced.

In one embodiment, the graphene power electrode distribution module includes:

the power grid voltage transformation unit is used for transforming high voltage of a power grid which can cause damage to a human body into low voltage which is safe to the human body through a transformer;

the low-voltage power supply unit is used for supplying power to the whole intelligent temperature control mattress system through the power grid voltage transformation unit;

the graphene power supply electrode distribution unit is used for distributing the graphene power supply electrodes in corresponding areas of the graphene partition heating system and corresponding the graphene power supply electrode distribution and the graphene partitions one by one; and in the heating control process, starting the graphene power supply electrode corresponding heating graphene partition heating system.

The working principle of the technical scheme is as follows: the high voltage of the power grid which may cause harm to human bodies is changed into low voltage which is safe to human bodies through a transformer through a power grid voltage transformation unit; the intelligent temperature control mattress system is integrally supplied with low-voltage power by a power grid voltage transformation unit by utilizing the performance characteristics of low voltage and high heat of the graphene material; the method comprises the steps of distributing graphene power supply electrodes in corresponding areas of a graphene partition heating system, and enabling the distribution of the graphene power supply electrodes to correspond to graphene partitions one by one; and in the heating control process, starting the graphene power supply electrode corresponding heating graphene partition heating system.

The beneficial effects of the above technical scheme are that: the high voltage of the power grid which can cause harm to human bodies is changed into the low voltage which is safe to the human bodies through the transformer by the power grid voltage transformation unit; the performance characteristics of low voltage and high heat of the graphene material can be fully utilized, the whole intelligent temperature control mattress system is supplied with low voltage power through the power grid voltage transformation unit, and the technical difficulty that other electric heating materials can be heated only under the condition of higher voltage can be solved; the graphene power supply electrodes are distributed in corresponding areas of the graphene subarea heating system, and the distribution of the graphene power supply electrodes and the graphene subareas can be in one-to-one correspondence; in the heating control process, the graphene power supply electrode corresponding heating graphene partition heating system is started, and coordination and consistency of the control electrode and the heating area are achieved.

In one embodiment, the warm-up start-stop control module includes:

the start-stop control action unit is used for receiving a heating start-stop signal and starting and stopping heating of the corresponding area of the graphene partition heating system;

the start-stop signal transmission unit is used for transmitting a heating start signal and a heating stop signal of the start-stop control action unit;

one end of the heating current conduction unit is connected with the graphene electrode connection unit, and the other end of the heating current conduction unit is connected with the start-stop control action unit;

and the graphene electrode connecting unit is used for connecting the power supply electrode and the heating current conducting unit.

The graphene temperature measurement module comprises:

the mattress surface temperature measurement dot array unit is used for carrying out array arrangement on the mattress surface sensors according to temperature measurement points, the lower layer of the array carries out contact type measurement and monitoring on the heating temperature of a graphene subarea heating system of the mattress, and the upper layer of the array carries out non-contact type induction measurement on the environment temperature and the human body surface temperature of the mattress;

the graphene temperature measurement sensing unit is used for measuring temperature through the graphene temperature measurement sensor;

the temperature measurement signal transmission unit is used for transmitting the temperature measurement signal of the graphene temperature measurement sensing unit;

the array area temperature analysis unit is used for calculating the contact ratio of state spectrum curves between a temperature measuring layer of the graphene temperature measuring sensor and the graphene temperature heating layer, and the calculation formula is as follows:

wherein, C₁₂Is the degree of coincidence of the spectral curves between layers, gamma₁(t) is the carbon atom velocity, gamma, of the temperature measuring layer of the graphene temperature measuring sensor at the t moment₁(0) The carbon atom speed at the initial moment of a temperature measuring layer of the graphene temperature measuring sensor is shown, exp represents an exponential formula with e as the base, and-i is an imaginary part;is the frequency, tau is the interval between lamination layers, gamma₂(t) is the carbon atom velocity, gamma, at time t of the graphene heating layer₂(0) The carbon atom velocity at the initial moment of the graphene heating layer; c₁₂The value is increased, the coincidence degree of the spectral curve is increased, and the interlayer thermal conductivity is increased; according to the measured value of the temperature measuring layer of the graphene temperature measuring sensor, the coincidence degree of the spectral curves between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer is calculated, the thermal conductivity between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer is analyzed, and the actual heating of the graphene heating layer is obtained through analysisThe temperature is analyzed and adjusted according to the surface temperature of the human body in the sleeping state and the ambient temperature in the sleeping state;

graphite alkene temperature measurement sensing unit includes: the capacitor comprises positive and negative electrode micro-interval capacitor plates, an inter-plate capacitor cavity and an inter-plate capacitor graphene filling material; the positive and negative micro-interval capacitor plates are used for forming positive and negative charge polar plates of the temperature measuring point temperature measuring sensor; the inter-plate capacitor cavity is used for spacing the inter-plate capacitor graphene filling material; the graphene composite filling material for the inter-plate capacitor is used for carrying out graphene composite filling in the space area of the inter-plate capacitor cavity.

The working principle of the technical scheme is as follows: receiving a heating start-stop signal, and starting and stopping heating of corresponding areas of the graphene partition heating system; the starting and stopping control can be carried out through the connection and disconnection of the transistor, and the voltage and current regulation in the heating process is carried out through a voltage control system and a current control system, so that the heating temperature regulation control in the heating process is realized; transmitting a heating starting signal of the heating starting control module and a heating stopping signal of the heating stopping control module; conducting heating current, wherein one end of the heating current is connected with the graphene electrode connecting unit, and the other end of the heating current is connected with the start-stop control action unit; the graphene electrode connecting unit is connected with the power electrode and the heating current conducting unit; the mattress surface sensors are arranged in an array mode according to temperature measuring points, the lower layer of the array carries out contact type measurement monitoring on the heating temperature of a graphene subarea heating system of the mattress, and the upper layer of the array carries out non-contact type induction measurement on the environment temperature and the human body surface temperature of the mattress; measuring the temperature through a graphene temperature measuring sensor; transmitting a temperature measurement signal of the graphene temperature measurement sensing unit;

calculating the contact ratio of state spectrum curves between a temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer; c₁₂The larger the value, the larger the coincidence degree of the spectral curve is, and the higher the interlayer thermal conductivity is; according to the measured value of the temperature measuring layer of the graphene temperature measuring sensor, the coincidence degree of the spectral curves between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer is calculated, so that the thermal conductivity between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer can be analyzed; analyzing to obtain the actual heating temperature of the graphene heating layer, and obtaining the actual heating temperature according to the actual heating temperatureAnalyzing and adjusting the heating temperature according to the surface temperature of a human body in a sleeping state and the ambient temperature in the sleeping state; the capacitor comprises positive and negative electrode micro-interval capacitor plates, an inter-plate capacitor cavity and an inter-plate capacitor graphene filling material; the contact plate of the sensor and the graphene heating layer can adopt a contact type heat conduction plate, the non-contact type heat conduction plate of the sensor can adopt a radiation type heating plate, and the graphene material has two performances of heat conduction and different heat effects, so that the multi-purpose action principle of one material can be realized; the positive and negative micro-interval capacitor plates are used for forming positive and negative charge polar plates of the temperature measuring point temperature measuring sensor; the inter-plate capacitor cavity can be used for filling materials for spacing inter-plate capacitor graphene; the graphene composite filling material for the inter-plate capacitor can be used for carrying out graphene composite filling in the space area of the inter-plate capacitor cavity.

The beneficial effects of the above technical scheme are that: the starting and stopping control can be carried out through the connection and disconnection of the transistor, and the voltage and current regulation in the heating process is carried out through a voltage control system and a current control system, so that the heating temperature regulation control in the heating process is realized; heating of the corresponding area of the graphene partition heating system can be started and stopped by receiving a heating start-stop signal; the heating starting signal of the heating starting control module can be transmitted through the transistor conducting voltage control, and the heating stopping signal of the heating stopping control module can be triggered through the transistor turning-off voltage control; the heating current is conducted, one end of the control circuit is connected with the graphene electrode connecting unit, the other end of the control circuit is connected with the start-stop control action unit, and the control circuit and the heating power circuit can respectively and independently operate, so that the control signal is not influenced by the voltage and current change in the heating process of the main heating circuit, the control system is more stable, and the heating start-stop process and the start-stop point are more accurate; the graphene electrode can be connected with a power supply electrode and a heating current conduction unit; array arrangement is carried out mattress surface sensor according to the point of measurement of temperature, can carry out contact measurement control to the graphite alkene subregion system of heating of mattress through array lower floor to can carry out non-contact induction measurement through array upper strata to the ambient temperature of mattress, human surface temperature, can adopt bi-polar to measure in turn, further reduce temperature sensor's quantity and type, through a measurement system, realize multiple temperature measurement sensorMeasured multi-functional effects; measuring the temperature through a graphene temperature measuring sensor, and transmitting a temperature measuring signal to an integrated data intelligent processing center through a transmission system; the thermal conductivity between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer can be analyzed by calculating the contact ratio of state spectrum curves between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer; c₁₂The larger the value, the larger the coincidence degree of the spectral curve is, and the higher the interlayer thermal conductivity is; according to the measured value of the temperature measuring layer of the graphene temperature measuring sensor, analyzing the actual heating temperature of the graphene heating layer by calculating the coincidence degree of the spectral curves between the temperature measuring layer of the graphene temperature measuring sensor and the graphene heating layer, and analyzing and adjusting the heating temperature according to the surface temperature of a human body in a sleeping state and the ambient temperature in the sleeping state; the positive and negative electrode micro-interval capacitor plates can form positive and negative electrode charge polar plates of the temperature measuring point temperature measuring sensor; the inter-plate capacitor cavity can be used for spacing inter-plate capacitor graphene filling materials; the inter-plate capacitor graphene composite filling material can perform graphene composite filling in the inter-plate capacitor cavity interval area; the contact type heat-conducting plate can be adopted by the contact type heat-conducting plate and the non-contact type heat-conducting plate of the sensor, the radiation type temperature rising plate can be adopted by the non-contact type heat-conducting plate of the sensor, the graphene material just has the performances of two heat conduction and different heat effects, and the structure can realize the effect of one material, multiple measurement modes and multiple temperature induction of double end faces.

In one embodiment, the graphene integrated intelligent temperature control system includes:

the comprehensive data acquisition module is used for acquiring various monitoring data of the sleep state through the data transmission acquisition system of each sleep state monitoring system to obtain the comprehensive sleep state monitoring data;

sleep state integrated monitoring data, including: the body temperature monitoring system comprises data of the position of a body in a sleeping state, data of the pressure of the position of the body, data of the body prediction position in the sleeping state and data of body temperature monitoring;

the control signal transmission module is used for transmitting the intelligent comprehensive temperature control information obtained by the comprehensive data intelligent processing center module to the graphene subarea heating system;

the comprehensive data intelligent processing module is used for intelligently processing the sleep state comprehensive monitoring data acquired by the comprehensive data acquisition module through the comprehensive data intelligent processing center to acquire intelligent comprehensive temperature control information; intelligent integrated temperature control information, comprising: heating information is carried out on the position where the body is located, pre-heating information is carried out on the predicted position of the body, body temperature monitoring and adjusting heating temperature information is controlled, and comprehensive intelligent temperature control information of the mattress is obtained; through intelligent comprehensive temperature control information, comprehensive intelligent temperature control of the graphene intelligent temperature control mattress is achieved.

The working principle of the technical scheme is as follows: collecting various monitoring data of the sleep state through the data transmission and collection system of each sleep state monitoring system to obtain comprehensive monitoring data of the sleep state; sleep state integrated monitoring data, including: the body temperature monitoring system comprises data of the position of a body in a sleeping state, data of the pressure of the position of the body, data of the body prediction position in the sleeping state and data of body temperature monitoring; the intelligent comprehensive temperature control information obtained by the comprehensive data intelligent processing center module is transmitted to the graphene subarea heating system; the sleep state comprehensive monitoring data acquired by the comprehensive data acquisition module is intelligently processed through an intelligent processing center to obtain intelligent comprehensive temperature control information; intelligent integrated temperature control information, comprising: heating information is carried out on the position where the body is located, pre-heating information is carried out on the predicted position of the body, body temperature monitoring and adjusting heating temperature information is controlled, and comprehensive intelligent temperature control information of the mattress is obtained; through intelligent comprehensive temperature control information, comprehensive intelligent temperature control of the graphene intelligent temperature control mattress is achieved.

The beneficial effects of the above technical scheme are that: collecting various monitoring data of the sleep state through the data transmission and collection system of each sleep state monitoring system to obtain comprehensive monitoring data of the sleep state; sleep state integrated monitoring data, including: the body temperature monitoring system comprises data of the position of a body in a sleeping state, data of the pressure of the position of the body, data of the body prediction position in the sleeping state and data of body temperature monitoring; the intelligent comprehensive temperature control information obtained by the comprehensive data intelligent processing center module is transmitted to the graphene subarea heating system; the sleep state comprehensive monitoring data acquired by the comprehensive data acquisition module is intelligently processed through an intelligent processing center to obtain intelligent comprehensive temperature control information; intelligent integrated temperature control information, comprising: heating information is carried out on the position where the body is located, pre-heating information is carried out on the predicted position of the body, body temperature monitoring and adjusting heating temperature information is controlled, and comprehensive intelligent temperature control information of the mattress is obtained; comprehensive intelligent temperature control of the graphene intelligent temperature control mattress is realized through intelligent comprehensive temperature control information; comprehensive data intelligent processing to sleep state monitoring can enable the adjustment of temperature control to be more suitable for the sleep state of a human body, and more reasonable accurate customized control and adjustment can be carried out according to different user groups and user groups.

While embodiments of the invention have been disclosed above, it is not limited to the applications set forth in the description and the embodiments, which are fully applicable in various fields of endeavor to which the invention pertains, and further modifications may readily be made by those skilled in the art, it being understood that the invention is not limited to the details shown and described herein without departing from the general concept defined by the appended claims and their equivalents.