CN212521281U - Take handrail thing to sit on with sign monitoring - Google Patents

Abstract

The utility model discloses a take handrail thing to sit on with sign monitoring relates to life furniture technical field, and its technical scheme main points are: a sitting tool with handrails and a function of physical sign monitoring comprises handrails on two sides, wherein a physical sign monitoring system is arranged on the sitting tool with handrails, and the physical sign monitoring system comprises a plurality of pairs of metal acquisition interfaces, wherein the pairs of metal acquisition interfaces are symmetrically arranged on the handrails on the two sides respectively and are used for acquiring physical sign signals; the physical sign detection device is connected with the metal acquisition interface and is used for detecting and processing physical sign signals; the main controller is connected with the physical sign detection device and is used for analyzing and calculating the signals obtained after detection and processing to obtain physical sign data; and the display device is connected with the main controller and used for displaying the physical sign data. The utility model discloses a take handrail thing to sit on makes the user need not understand it for purpose with sign monitoring, just can know the physiological information of oneself, knows the health status of oneself.

Description

Take handrail thing to sit on with sign monitoring

Technical Field

The utility model belongs to the technical field of life furniture technique and specifically relates to a take handrail thing to sit on with sign monitoring is related to.

Background

In the 21 st century, commercial and scientific competition is more and more intense, overtime becomes a normal state, and sudden death and syncope phenomena are common in various places. How to reduce or prevent sudden death and syncope has become the subject of major research in health management. The transition from an overworked low-risk group, to an intermediate-risk group, and finally to a high-risk group is actually a quantitative to qualitative change process in which changes in vital sign data of a person are most obvious.

In modern life, people sit on a sofa, in front of a tea table and the like while working, entertaining or resting in front of a computer. Among them, most people are sitting in the normal state, but many seats include chairs, sofas, massage chairs, etc. and all have armrests, and such seats with armrests only provide more comfortable experience for people; but it can not assist in collecting and acquiring the health sign data of the user, and thus can not play a health monitoring role for the user.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model aims to provide a take handrail thing to sit on with sign monitoring for the user need not be for it at will, just can know the physiological information of oneself, knows the health status of oneself.

The above utility model discloses an above-mentioned utility model purpose can realize through following technical scheme:

a sitting tool with armrests and physical sign monitoring function comprises armrests on two sides, a physical sign monitoring system is arranged on the sitting tool with armrests, the physical sign monitoring system comprises,

the metal acquisition interfaces are a plurality of pairs and are respectively and symmetrically arranged on the handrails at the two sides and are used for acquiring physical sign signals;

the physical sign detection device is connected with the metal acquisition interface and is used for detecting and processing physical sign signals;

the main controller is connected with the physical sign detection device and is used for analyzing and calculating the signals obtained after detection and processing to obtain physical sign data;

and the display device is connected with the main controller and used for displaying the physical sign data.

By adopting the technical scheme, when a user sits on the seat in daily life and work, the two hands are placed on the handrails on the two sides simultaneously, so that the two hands are respectively connected with the metal acquisition interfaces on the handrails on the two sides, the metal acquisition interfaces can acquire physical sign information of the human body through the two hands, the physical sign information is transmitted to the physical sign detection device so as to perform signal processing on the acquired physical sign information (including extracting characteristic signals, and performing interference removal, analysis, synthesis, transformation, operation and other processing to obtain required characteristic signals), and then the characteristic data is analyzed and operated by the main controller to obtain physical sign data about the user so as to be displayed on the display device, so that the user can know the self physical condition in time; the main controller is pre-stored with operation methods related to medical aspects (for example, operation methods for obtaining various data according to an electrocardiogram, which are the existing technologies in the medical field), and the scheme introduces a health concept into the seat and integrates health monitoring and daily life; therefore, the user can know the physiological information and the health condition of the user without intending to do so.

The utility model discloses further set up to: the physical sign detection device comprises a body sign detection device,

the analog switch is connected with the metal acquisition interface and used for distributing the physical sign signals to the body fat detection module or the ECG module;

the body fat detection module is connected with the analog switch and is responsible for detecting the impedance of the human body;

the ECG module is connected with the analog switch and is responsible for amplifying, shaping and filtering the human ECG signal and then sending the signal to the processor;

and the processor is respectively connected with the body fat detection module and the ECG module, is used for post-processing the ECG signal and the human body impedance signal, and is responsible for communicating with the main controller.

By adopting the technical scheme, the metal acquisition interface is just like an electrocardio monitoring electrode plate, sign signals of the metal acquisition interface are distributed to a body fat detection module or an ECG module through an analog switch for use, the body fat detection module is used for detecting the impedance of a human body, the ECG module is used for amplifying, shaping and filtering the ECG signals of the human body, and finally the signals are sent to the main controller through the processor for analysis and operation to obtain sign data (including HR heart rate, RR respiration rate, SNA anxiety index, HRV heart rate variability, ARR arrhythmia, QT interval, PBF body fat rate, PBW body moisture rate, FAG fatigue grade and the like) about a user; and judging the state of the measuring personnel by combining the cardiac function, the respiratory function and the fatigue grade, and providing reminding information according to the health evaluation model and the chronic disease risk.

The utility model discloses further set up to: the processor and the main controller are communicated by a universal asynchronous receiving and transmitting transmitter.

By adopting the technical scheme, the universal asynchronous receiving and transmitting transmitter is generally called UART, the ECG module (electrocardiogram sampling module) outputs data in a UART serial mode, and the communication speed can be higher by adopting the universal asynchronous receiving and transmitting transmitter.

The utility model discloses further set up to: the processor is connected with a wireless communication module and is connected with a mobile terminal through the wireless communication module.

By adopting the technical scheme, the wireless communication module is connected with the mobile terminal so as to send the physical sign data to the mobile terminal, so that the user and the family of the user can conveniently check and record the physical sign data.

The utility model discloses further set up to: the wireless communication module is a Bluetooth module, a WiFi module or an NB-IOT module.

The utility model discloses further set up to: the metal collecting interfaces are symmetrically arranged on the upper surfaces of the handrails on the two sides respectively.

To sum up, the utility model discloses a beneficial technological effect does: when a user sits on the seat, only two hands are respectively placed on the armrests on the two sides, physical sign information of the human body can be acquired through the two arms by using the metal acquisition interface, physical sign data of the user can be obtained after the physical sign information is analyzed and calculated by the main controller and is displayed on the display device, and health monitoring and daily life are integrated; therefore, the user can know the physiological information and the health condition of the user without intending to do so.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a block diagram of the system of the present invention;

figure 3 is a schematic diagram of a universal asynchronous receiver transmitter.

In the figure, 1, a handrail; 2. a metal collection interface; 3. a physical sign detection device; 31. an analog switch; 32. a body fat detection module; 33. an ECG module; 34. a processor; 4. a main controller; 5. a display device; 6. a universal asynchronous transceiver transmitter; 7. a wireless communication module; 8. a mobile terminal.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Referring to fig. 1, 2 and 3, the sitting device with armrest for monitoring physical signs disclosed by the present invention comprises armrests 1 on both sides, wherein the sitting device with armrest is provided with a physical signs monitoring system, and the physical signs monitoring system comprises a metal acquisition interface 2, a physical signs detection device 3, a main controller 4 and a display device 5; the metal acquisition interfaces 2 are a plurality of pairs and are respectively and symmetrically arranged on the upper surfaces of the armrests 1 on the two sides (of course, the metal acquisition interfaces 2 can also be symmetrically arranged on the contact parts of the two large legs of the seat, and the effect is the same by detecting the two thighs instead of detecting the two arms); the physical sign detection device 3 is connected with the metal acquisition interface 2 and is used for detecting and processing physical sign signals; the main controller 4 is connected with the physical sign detection device 3 and is used for analyzing and calculating the signals obtained after detection and processing to obtain physical sign data; and the display device 5 is connected to the main controller 4 and used for displaying the physical sign data.

In daily life and work, when a user sits on the seat, the two hands are placed on the armrests 1 on the two sides at the same time, so that the two hands are respectively connected with the metal acquisition interfaces 2 on the armrests 1 on the two sides, the metal acquisition interfaces 2 can acquire physical sign information of the human body through the arms of the two hands, the physical sign information is transmitted to the physical sign detection device 3 to perform signal processing on the acquired physical sign information (including extracting characteristic signals, and performing interference removal, analysis, synthesis, transformation, operation and the like to obtain required characteristic signals), and then the characteristic data is analyzed and operated through the main controller 4 to obtain physical sign data about the user so as to be displayed on the display device 5, so that the user can know the self physical condition in time; the main controller 4 is pre-stored with operation methods related to medical treatment (for example, operation methods for obtaining various data according to an electrocardiogram, which are existing technologies in the medical treatment field), and the scheme introduces a health concept into the seat, so that health monitoring and daily life are integrated; therefore, the user can know the physiological information and the health condition of the user without intending to do so.

Here it is to be understood that: the electrocardiogram is the bioelectrical variation of the heart during each movement cycle. It is the manifestation of the reciprocal activity of the heart, which is the excitation process from the pacemaker, atrium, and ventricle. Electrocardiographic examination has an important meaning for the diagnosis of cardiovascular diseases: it has important diagnostic value for arrhythmia and conduction disorder; the diagnosis of myocarditis, coronary insufficiency and pericarditis is greatly facilitated. Electrocardiographic examination is used for examination of various diseases such as arrhythmia, ventricular atrial hypertrophy, myocardial infarction, arrhythmia, and myocardial ischemia. Can reflect the degree and development process of myocardial damage and the functional structure condition of atria and ventricles. In addition, Brugada syndrome, long QT and short QT syndrome, etc. which cannot be found by other examinations can also be found by electrocardiographic examination. For example, heart rate is calculated from an electrocardiogram signal: the number of beats per minute of the atria is referred to as the atrial rate and the number of beats per minute of the ventricles is referred to as the ventricular rate. The heart rate calculated by means of an electrocardiogram is in fact the number of electrical activations of the heart per minute. Each QRS wave on the electrocardiogram normally represents a heartbeat. The heart rate is obtained by converting the heart rate within a certain time into the heart rate per minute; therefore, the electrocardiogram signal can be used for obtaining the physical sign data of a plurality of people by applying the modern medical technology.

The PBF body fat rate and the PBW body water content rate of the measurer can be calculated according to the sex, the height and the weight, and the obesity degree and the possible chronic disease risk can be judged by combining the BMI index; and judging the working state of the measuring personnel by combining the cardiac function, the respiratory function and the fatigue grade, and providing reminding information according to the health assessment model and the chronic disease risk.

Wherein, the physical sign detecting device 3 comprises an analog switch 31, a body fat detecting module 32, an ECG module 33 and a processor 34; the analog switch 31 is connected to the metal acquisition interface 2 and is used for distributing the physical sign signals to the body fat detection module 32 or the ECG module 33; the body fat detection module 32 is connected with the analog switch 31 and is responsible for detecting the impedance of the human body; the ECG module 33 is connected with the analog switch 31 and is responsible for amplifying, shaping and filtering the human ECG signal and then sending the signal to the processor 34; and the processor 34 is respectively connected with the body fat detection module 32 and the ECG module 33, is used for post-processing the ECG signal and the human body impedance signal, and is responsible for communicating with the main controller 4. In the scheme, the metal acquisition interface 2 is just like an electrocardiogram monitoring electrode plate, sign signals of the metal acquisition interface 2 are distributed to a body fat detection module 32 or an ECG module 33 through an analog switch 31 for use, the body fat detection module 32 is used for detecting the impedance of a human body, the ECG module 33 is used for amplifying, shaping and filtering the ECG signals of the human body, and finally the signals are sent to the main controller 4 through the processor 34 for analysis and operation to obtain sign data (including HR heart rate, RR respiration rate, SNA anxiety index, HRV heart rate variability, ARR arrhythmia, QT interval, PBF body fat rate, PBW body water content rate, FAG fatigue level and the like) about a user; and judging the state of the measuring personnel by combining the cardiac function, the respiratory function and the fatigue grade, and providing reminding information according to the health evaluation model and the chronic disease risk.

In this embodiment, the processor 34 communicates with the main controller 4 by providing the UART 6. The UART 6 is generally called UART, the ECG module 33 (ECG sampling module) outputs data in UART serial mode, and the communication speed can be increased by adopting the UART 6.

The processor 34 is connected to the wireless communication module 7, and the processor 34 is connected to the mobile terminal 8 through the wireless communication module 7. Is connected with the mobile terminal 8 through the wireless communication module 7 to send the physical sign data to the mobile terminal 8 so as to be convenient for the user and the family members of the user to check and record.

The wireless communication module 7 is a bluetooth module, a WiFi module or an NB-IOT module.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (6)

1. A seat with armrest and with monitoring of physical signs, comprising two side armrests (1), characterized in that: the sitting tool with the armrest is provided with a physical sign monitoring system which comprises,

the metal acquisition interfaces (2) are a plurality of pairs and are respectively and symmetrically arranged on the handrails (1) at the two sides and are used for acquiring physical sign signals;

the physical sign detection device (3) is connected with the metal acquisition interface (2) and is used for detecting and processing physical sign signals;

the main controller (4) is connected with the physical sign detection device (3) and is used for analyzing and calculating the signals obtained after detection and processing to obtain physical sign data;

and the display device (5) is connected to the main controller (4) and is used for displaying the physical sign data.

2. The armrest seating unit of claim 1, wherein: the physical sign detection device (3) comprises,

the analog switch (31) is connected to the metal acquisition interface (2) and is used for distributing the physical sign signals to the body fat detection module (32) or the ECG module (33);

the body fat detection module (32) is connected with the analog switch (31) and is responsible for detecting the impedance of the human body;

the ECG module (33) is connected with the analog switch (31) and is responsible for amplifying, shaping and filtering the human ECG signal and then sending the signal to the processor (34);

and the processor (34) is respectively connected with the body fat detection module (32) and the ECG module (33), is used for post-processing the ECG signal and the human body impedance signal, and is responsible for communicating with the main controller (4).

3. The armrest seating unit of claim 2, wherein: the processor (34) is communicated with the main controller (4) through a universal asynchronous receiving and transmitting transmitter (6).

4. The armrest seating unit of claim 2, wherein: the processor (34) is connected with a wireless communication module (7), and the processor (34) is connected with a mobile terminal (8) through the wireless communication module (7).

5. The armrest seating unit of claim 4, wherein: the wireless communication module (7) is a Bluetooth module, a WiFi module or an NB-IOT module.

6. The armrest seating unit of claim 1, wherein: the metal acquisition interfaces (2) are respectively and symmetrically arranged on the upper surfaces of the handrails (1) on the two sides.

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