WO2018018923A1

WO2018018923A1 - Reclining-style physical sign checking apparatus and method

Info

Publication number: WO2018018923A1
Application number: PCT/CN2017/079157
Authority: WO
Inventors: 张贯京
Original assignee: 深圳市前海安测信息技术有限公司
Priority date: 2016-07-23
Filing date: 2017-03-31
Publication date: 2018-02-01
Also published as: CN106175728A

Abstract

Disclosed are a reclining-style physical sign checking apparatus and method. The apparatus comprises a monitoring table (1), an upright board (2) and a support frame (3). One end of the monitoring table (1) is provided with a head covering board (10), the head covering board (10) being provided with an infrared temperature sensing probe (101). A sliding rail (11) is fixed at two sides of the other end of the monitoring table (1). A sliding post (12) is provided between the two sliding rails (11). A footboard (13) is fixed on the sliding post (12), and a pressure sensor (14), an infrared range sensor (15) and an electric motor driver (16) are provided on the footboard (13). The monitoring table (1) is further provided with an electronic weighing scale (17). A microprocessor (21) is provided in the upright board (2). A display screen (22) is embedded in an outer surface of the upright board (2). An arm sleeve (4) and an electrocardiograph apparatus (5) are provided on the upright board (2), and an inner wall of the cavity of the arm sleeve (4) is provided with a blood pressure sensor (41) and a pulse sensor (42). The electrocardiograph apparatus (5) comprises 12-lead electrodes (51) and lead wires (52), and the 12-lead electrodes (51) are connected to the microprocessor (21) via the lead wires (52). The reclining-style physical sign checking apparatus and method can conveniently perform checks on a plurality of physical signs of a person unable to stand upright, has complete checking functions, and has a high degree of automation and a high degree of accuracy in examination.

Description

Technical field

[0001] The present invention relates to the field of medical devices, and in particular, to a flat lying sign detection device and method.

Background technique

[0002] At present, chronic diseases such as diabetes, hypertension, and cardiovascular and cerebrovascular diseases are diseases that are extremely harmful to humans, and may cause a large number of people who have no standing ability such as patients with hemiplegia or stroke. In order to restore the health of people without standing ability, doctors or health managers usually analyze the patient's BMI index, body temperature, blood pressure, pulse and electrocardiogram to specify a health management plan for people without standing ability. Although the existing medical integrated machine can integrally detect a plurality of vital signs such as "temperature, blood pressure, pulse, heart rate", it is necessary for the user to stand or sit to measure the physical parameters. However, existing medical all-in-one machines are inconvenient to measure vital signs (such as BMI index and ECG parameters) of people without standing ability, resulting in incomplete functions and low degree of automation. Therefore, it is necessary to provide a flat-body sign detecting device and method suitable for a patient without standing ability to meet the health sign detection needs of a group of patients without standing ability.

technical problem

[0003] The main object of the present invention is to provide a flat lying sign detection device and method, which aims to solve the problem that the existing medical integrated machine is inconvenient to measure the vital signs of the non-standing ability, resulting in incomplete function and low degree of automation. problem.

Problem solution

Technical solution

[0004] In order to achieve the above object, the present invention provides a flat reclining sign detecting device, comprising a monitoring table, a column plate and a support frame, wherein one end of the monitoring table is provided with a head cover, and the head cover is provided with infrared a temperature sensing probe for sensing the temperature of the user's forehead as the user's body temperature data;

[0005] a slide rail is fixed on each side of the other end of the monitoring platform, and a slide bar is disposed between the two slide rails, and the pedal is fixed with a foot pedal, and the foot pedal is provided with a pressure sensor, An infrared distance measuring sensor and a motor driver, wherein the motor driver is configured to drive the sliding rod to slide along the sliding rail so that The foot pedal is moved to a position of a user's feet lying on the monitoring platform, and the pressure sensor is configured to detect a pressure value of a user's feet contacting the foot pedal. The infrared ranging sensor is configured to detect a distance between the foot pedal and the head cover as the height data of the user when the pressure value is not zero, and the monitoring station is further provided with an electronic weight scale, An electronic weight scale is used to measure the user's weight data;

[0006] The pillar plate is provided with a microprocessor, the outer surface of the pillar plate is embedded with a display screen, the pillar plate is provided with an arm sleeve and an electrocardiogram monitoring device, and the ECG monitoring device includes twelve a lead electrode and a lead wire, wherein the twelve lead electrode is connected to the microprocessor through a lead wire, and an inner wall of the cavity of the arm sleeve is provided with a blood pressure sensor and a pulse sensor, and the blood pressure sensor is used for Detecting a blood pressure value of the user, the pulse sensor being configured to detect a pulse value of the user;

[0007] The microprocessor is configured to calculate a BMI index of the user according to the height data and the weight data, and obtain the ECG of the user by using the signal sampling process, and the BMI value, the electrocardiogram, Body temperature data, blood pressure values, and pulse values are displayed on the display.

[0008] Preferably, one end of the column plate is provided with a concave port, and the monitoring platform is fixedly connected to the column plate through the concave port, and the support frame is used for supporting the monitoring platform.

[0009] Preferably, the arm sleeve is fixed to one side edge of the concave mouth, the arm sleeve is an annular cavity structure, and the blood pressure sensor and the pulse sensor are disposed adjacent to the arm sleeve. The inner wall of the cavity.

[0010] Preferably, the twelve lead electrode comprises three limb lead electrodes, three pressurized lead electrodes and six chest lead electrodes.

[0011] Preferably, the infrared temperature sensing probe is fixed on the head cover by an elbow, and when the user lies on the monitoring platform, the direction and position of the elbow are adjusted. The infrared temperature probe is aimed at the user's forehead to sense the temperature of the user's forehead.

[0012] Preferably, the support frame is provided with a power switch and a communication interface, and the infrared temperature probe, an electronic weight scale, a pressure sensor, an infrared distance measuring sensor, a motor driver, a display screen, a power switch, and a communication The interfaces are all electrically connected to the microprocessor.

[0013] The present invention also provides a flat lying sign detection method, which is applied to a flat lying sign detection device, the device includes a monitoring table, a column plate and a support frame, and one end of the monitoring table is provided with a head cover The head cover is provided with an infrared temperature sensing probe, and one sliding rail is fixed on each side of the other end of the monitoring platform, two A slide bar is disposed between the slide rails, and a foot pedal is fixed on the slide bar. The foot pedal is provided with a pressure sensor, an infrared distance measuring sensor and a motor driver. The column plate is provided with a microprocessor. The outer surface of the pillar plate is inlaid with a display screen, the pillar plate is provided with an arm sleeve and an electrocardiogram monitoring device, and the ECG monitoring device comprises a 12-lead electrode and a lead wire, and the inner wall of the cavity of the arm sleeve A blood pressure sensor and a pulse sensor are provided, wherein the method comprises the steps of:

[0014] when the power supply on the support frame is set, the motor driver drives the sliding rod to slide on the slide rail of the monitoring platform along the direction of the user's feet;

[0015] the pressure sensor detects a pressure value of a user's feet contacting the foot pedal;

[0016] the microprocessor determines whether the pressure value is zero;

[0017] when the pressure value is not zero, the microprocessor controls the motor driver to stop rotating to stop the sliding bar from sliding on the sliding rail of the monitoring platform;

[0018] the infrared ranging sensor detects a distance between the foot pedal and the head cover as a height data of the user, and the electronic weight meter measures the weight data of the user;

[0019] the microprocessor calculates a BMI index of the user according to the height data and the weight data;

[0020] the twelve lead electrode collects an ECG signal of the user, and sends the collected ECG signal to the microprocessor through a lead wire;

[0021] the microprocessor sends the ECG signal to the user's electrocardiogram through signal sampling processing;

[0022] The infrared temperature sensor emits infrared light to sense the temperature of the user's forehead as the user's body temperature data; [0023] the blood pressure sensor detects a user's blood pressure value, and the pulse sensor detects a user's pulse value; [0024] The microprocessor displays a BMI value, an electrocardiogram, a body temperature data, a blood pressure value, and a pulse value of the user on the display screen.

[0025] Preferably, the flat rectal sign detection method further comprises the steps of: the microprocessor transmitting the BMI value, the electrocardiogram, the body temperature data, the blood pressure value and the pulse value of the user through a communication interface disposed on the support frame To the health management platform of the medical health center.

[0026] Preferably, the step of the microprocessor to obtain the electrocardiogram of the user by signal sampling processing includes the following steps: the microprocessor performs the ECG signal collected by the twelve lead electrodes The 吋 clock sampling process and the 吋 clock conversion process obtain a lead ECG waveform; the microprocessor converts the lead ECG waveform into a user's electrocardiogram. [0027] the infrared temperature sensing probe is fixed on the head cover by an elbow, and when the user lies flat on the monitoring platform, the infrared temperature is sensed by adjusting the direction and position of the bending tube. The probe is aimed at the user's forehead to sense the temperature of the user's forehead.

Advantageous effects of the invention

Beneficial effect

Compared with the prior art, the flat rectal sign detecting device and method of the present invention adopts the above technical solutions, and achieves the following technical effects: the method of detecting the vital signs by the user lying on the monitoring platform, and detecting the same The function is complete and the degree of automation is high. It can not only easily check multiple vital signs (including BMI, ECG, body temperature data, blood pressure and pulse value) for people without standing ability (such as hemiplegia patients and stroke patients). It also allows the user to perform physical examination and relax the body, thus improving the accuracy of the sign detection.

Brief description of the drawing

DRAWINGS

1 is a schematic structural view of a preferred embodiment of a flat rectal sign detecting device of the present invention;

2 is a schematic diagram showing the circuit connection of a preferred embodiment of the lying type sign detecting device;

3 is a flow chart of a preferred embodiment of the flat rectal sign detection method of the present invention.

[0032] The objects, features, and advantages of the present invention will be further described in conjunction with the embodiments.

BEST MODE FOR CARRYING OUT THE INVENTION

The specific embodiments, structures, features and utilities of the present invention are described in detail below with reference to the drawings and the preferred embodiments. It is understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

1 and FIG. 2, FIG. 1 is a schematic structural view of a preferred embodiment of the flat rectal sign detecting device of the present invention; and FIG. 2 is a schematic view showing the circuit connection of a preferred embodiment of the flat reclining sign detecting device. In this embodiment, the lying type physical sign detecting device includes, but is not limited to, a monitoring table 1, a column plate 2, and a support frame 3, and one end of the column plate 2 is provided with a concave port 20, and the monitoring The table 1 is fixed to the column plate 2 through the concave opening 20 Connected, the support frame 3 is used to support the monitoring station 1. A microprocessor 21 is disposed in the pillar plate 2, and an outer surface of the pillar plate 2 is embedded with a display screen 22.

[0035] One end of the monitoring table 1 is provided with a head cover 10, and the head cover 10 is provided with an infrared temperature sensing probe 101. The infrared temperature sensing probe 101 is fixed to the head cover 10 via an elbow 102 for emitting infrared rays to sense the temperature of the user's forehead as the user's body temperature data. When the user performs the physical examination, the user's body passes through the concave opening 20 of the pillar plate 2 and lies flat on the monitoring table 1, so that the user needs to straighten the feet and the head should be with the head cover 10 Contact to measure the user's height data and body temperature data. When the user lies flat on the monitoring table 1, the infrared temperature sensing probe 101 can be aligned with the forehead of the user by adjusting the direction and position of the curved tube 102 to improve the accuracy of measuring the user's body temperature data.

[0036] A sliding rail 11 is fixed on each of the two ends of the other end of the monitoring platform 1. A sliding rod 12 is disposed between the two sliding rails 11, and the sliding pedal 12 is fixed with a pedal 13 A pressure sensor 14, an infrared distance measuring sensor 15, and a motor driver 16 are provided on the 13 . The motor driver 16 is used to drive the sliding rod 12 to slide freely along the sliding rail 11, thereby driving the pedal 13 to move. The monitoring station 1 is further provided with an electronic body weight meter 17 for measuring the user's body weight data and transmitting the body weight data to the microprocessor 21. The infrared ranging sensor 15 is for emitting the distance between the infrared detecting foot pedal 13 and the head cover 10 as the height data of the user.

[0037] In the present embodiment, when the pressure sensor sense 14 detects that the pressure value of the footboard 13 is not zero (ie, the user's feet touch the foot pedal 13), the microprocessor 21 is used. Controlling the rotation of the motor driver 16 causes the slide bar 12 to stop sliding on the slide rail 11 of the monitoring table 1, and the infrared distance measuring sensor 15 emits the distance between the infrared detecting foot pedal 13 and the head cover 10 as the height of the user. Data, and the user's weight data is measured by an electronic weight scale 17. The microprocessor 21 is further configured to calculate a BMI value of the user according to the height data and the weight data of the user, the BMI value is also referred to as a body mass index, and the English is a Body Mass Index (BMI), and the microprocessor 21 The weight of kilograms divided by the height of the square meters to obtain the BMI value, which is currently used in the international community to measure the degree of fat and health and a standard.

[0038] One side edge of the concave opening 20 is fixed with an arm sleeve 4, which is an annular cavity structure. The inner wall of the cavity of the arm sleeve 4 is provided with a blood pressure sensor 41 and a pulse sensor 42. The blood pressure sensor 41 and the pulse sensor 42 are disposed adjacent to the inner wall of the cavity of the arm sleeve 4, thereby facilitating measurement of the user by the peer. Blood pressure and pulse value. When the user's arm extends into the cavity of the arm sleeve 4 and with the blood pressure sensor 41 and a pulse sensor 42A, the blood pressure sensor 41 is configured to monitor a user's blood pressure value (including systolic blood pressure and diastolic blood pressure), and send the user's blood pressure value to the microprocessor 21. The pulse sensor 42 is used to monitor the user's pulse value and send the user's pulse value to the microprocessor 21.

[0039] The electrocardiographic monitoring device 5 is fixed on the column plate 2, and the ECG monitoring device 5 includes a 12-lead electrode 51 and a lead wire 52. The 12-lead electrode 51 is connected to the micro-processing through the lead wire 52. On the 21st. The twelve lead electrode 51 includes three limb lead electrodes, three pressurized lead electrodes, and six chest lead electrodes. The twelve lead electrodes 51 can be respectively adsorbed on different parts of the user's body, including the human chest and the peripheral parts of the chest, such as the chest, the underarm, the neck, the abdomen and the like. The twelve lead electrodes 51 are used to respectively collect electrocardiographic signals of different parts of the user's body, and the collected ECG signals are sent to the microprocessor 21 through the lead wires 52. Since the 12-lead electrode 51 is used to collect the ECG signals of different body parts of the user, the ECG signal of the user can be accurately collected, thereby improving the accuracy of the ECG detection result.

[0040] The microprocessor 21 obtains an electrocardiogram waveform by the user's electrocardiographic signal through signal sampling processing, and converts the electrocardiographic waveform into a user's electrocardiogram. Specifically, the microprocessor 21 performs the chirp clock sampling process and the chop clock conversion process to obtain a lead electrocardiogram waveform, and converts the lead electrocardiogram waveform into a user's electrocardiogram. In an embodiment, the microprocessor 21 can control the sampling rate by changing the sampling chirp frequency. For example, if the microprocessor 21 samples every 0.5 ms or lms or 2 ms, the corresponding ECG signals are sampled at 2 KSps, IKSps, and 500 Sps, respectively.

In the present embodiment, the pressure sensor 14, the infrared distance measuring sensor 15, the motor driver 16, the electronic weight scale 17, the display screen 22, and the infrared temperature sensing probe 101 are all connected to the microprocessor 21. The display screen 22 is an LCD or LED display unit, and is electrically connected to the microprocessor 21 for displaying the user's vital sign data, including the user's BMI value, electrocardiogram, body temperature data, and blood pressure. Value and pulse value for the doctor to understand the user's health.

[0042] One side of the support frame 3 is provided with a power switch 31 and a communication interface 32. The power interface 31 is electrically connected to the microprocessor 21 for controlling the turning on or off of the microprocessor 21. The communication interface 32 is a communication port supporting a wireless transmission network such as Bluetooth or/and WiFi, and is used for sending the user's vital signs data (including BMI value, electrocardiogram, body temperature data, blood pressure value and pulse value) to medical health. The center's health management platform provides a basis for doctors to manage their health. [0043]

[0044] The present invention also provides a flat lying sign detection method. As shown in Fig. 3, Fig. 3 is a flow chart showing a preferred embodiment of a flow chart of a preferred embodiment of the flat rectal physique detecting method of the present invention. In this embodiment, referring to FIG. 1 and FIG. 2, the flat lying sign detection method includes the following steps:

[0045] Step S30, the motor driver drives the sliding rod to slide on the sliding rail of the monitoring platform along the direction of the user's feet; specifically, when the user lies flat on the monitoring platform 1, the user needs to straighten the feet and The head should be in contact with the head cover 10, and the power switch 31 is driven, and the motor driver 16 drives the slide bar 12 to slide on the slide rail 11 of the monitoring table 1 along the direction of the user's feet, thereby driving the pedal 13 moves in the direction of the user's feet.

[0046] Step S31, the pressure sensor senses whether the pressure value of the foot pedal is zero; specifically, the pressure sensor 14 senses whether the pressure value of the foot pedal 13 is zero. If the pressure value of the foot pedal is zero, the flow returns to step S30; if the pressure value of the foot pedal is not zero, the flow proceeds to step S32.

[0047] Step S32, controlling the motor driver to stop rotating, so that the sliding rod stops sliding on the sliding rail of the monitoring platform; specifically, when the pressure sensor sense 14 detects that the pressure value of the footboard 13 is not zero (ie, the user's double The foot contacts the foot pedal 13) 吋, the microprocessor 21 controls the motor driver 16 to stop rotating so that the slide bar 12 stops sliding on the slide rail 11 of the monitoring table 1.

[0048] Step S33, the infrared ranging sensor detects the distance between the foot pedal and the head cover as the height data of the user, and the electronic weight meter measures the weight data of the user; specifically, the infrared ranging sensor 15 emits infrared rays. The distance between the footboard 13 and the head cover 10 is detected as the height data of the user, and the height data of the user is transmitted to the microprocessor 21. The electronic weight scale 17 measures the user's weight data and transmits the user's weight data to the microprocessor 21.

[0049] Step S34, the microprocessor calculates the BMI index of the user according to the height data and the weight data of the user. Specifically, the microprocessor 21 calculates the BMI value of the user according to the height data and the weight data of the user. The BMI value is also called the body mass index. The microprocessor 21 divides the weight in kilograms by the square of the height and the square of the BMI. This BMI value is a commonly used standard for measuring the fatness of the human body and whether it is healthy.

[0050] Step S35, the twelve lead electrodes collect the ECG signals of the user, and send the collected ECG signals to the microprocessor through the lead wires. In this embodiment, the twelve leads The electrode 51 includes twelve core electrode sheets, and each of the core electrode sheets is respectively adsorbed on different parts of the user's body, including the human body chest and The area around the chest, such as the chest, underarm, neck, abdomen, etc. The twelve lead electrodes 51 respectively collect electrocardiographic signals of different parts of the user's body, and transmit the collected ECG signals to the microprocessor 21 through the lead wires 52. Since the 12-lead electrode 51 is used to collect the ECG signals of different body parts of the user, the ECG signal of the user can be accurately collected, thereby improving the accuracy of the ECG detection result.

[0051] Step S36, the microprocessor obtains the electrocardiogram of the user by sampling the ECG signal; specifically, the microprocessor 21 obtains the ECG waveform by the signal sampling process of each ECG signal, and the ECG is The waveform is converted to the user's electrocardiogram. In this embodiment, the microprocessor 21 performs each of the ECG signals of the electrode interface 3 to perform a chirp clock sampling process and a chirp clock conversion process to obtain a lead ECG waveform, and converts the lead ECG waveform into The user's ECG. The microprocessor 21 can control the sampling rate by changing the sampling clock frequency. For example, the microprocessor 21 samples every 0.5 ms or lms or 2 ms, and the sampling rates of the corresponding ECG signals are 2 KSps, IKSps, and 500 Sps, respectively.

[0052] Step S37, the infrared temperature sensing probe emits infrared light to sense the temperature of the user's forehead as the body temperature data of the user; specifically, the infrared temperature sensing probe 101 senses the temperature of the user's forehead by emitting infrared rays as the user's Body temperature data. When the user lies flat on the monitoring platform 1, the infrared temperature sensing probe 101 can be aligned with the forehead of the user by adjusting the direction and position of the curved tube 102, so as to improve the accuracy of measuring the user's body temperature data. Sex.

[0053] Step S38, the blood pressure sensor detects the blood pressure value of the user, and the pulse sensor detects the pulse value of the user; when the user's arm reaches the cavity of the arm sleeve 4 and is connected to the blood pressure sensor 41 and the pulse sensor 42, the blood pressure The sensor 41 monitors the user's blood pressure values (including systolic blood pressure and diastolic blood pressure) and transmits the user's blood pressure value to the microprocessor 21. The pulse sensor 42 monitors the user's pulse value and sends the user's pulse value to the microprocessor 21. The blood pressure sensor 41 and the pulse sensor 42 are disposed adjacent to the inner wall of the cavity of the arm sleeve 4, thereby facilitating simultaneous measurement of the blood pressure value and the pulse value of the user.

[0054] Step S39, the microprocessor displays the BMI index, the electrocardiogram, the body temperature data, the blood pressure value, and the pulse value of the user on the display screen, and sends the data to the health management platform through the communication interface. Specifically, the microprocessor 21 displays the BMI value, the electrocardiogram, the body temperature data, the blood pressure value, and the pulse value of the user on the display screen 2 2 for the doctor to know the health status of the user. In this embodiment, the microprocessor 21 also sends the BMI value, the electrocardiogram, the body temperature data, the blood pressure value, and the pulse value of the user through the communication interface 32. To the health management platform of the medical health center, it provides a basis for doctors to manage the health of users.

[0055] It should be noted that the user refers to any group of people who need to perform physical examination, including but not limited to, non-standing people such as healthy people, sub-health groups, disabled people, hemiplegia patients, and stroke patients. The flat rectal sign detecting device and method of the invention can simultaneously measure the user's BMI value, electrocardiogram, body temperature data, blood pressure value and pulse value multiple vital signs data, and has the advantages of multifunctional integration, automatic function, etc. The individual detection function is highly integrated into one device and is suitable for home and community medical units, providing good help and support for medical treatments such as telemedicine and home health care. In addition, the invention adopts a method in which the user lies on the monitoring platform to perform the physical sign detection, and the inspection function is complete and the degree of automation is high, and the user can be conveniently carried out for the non-standing person (for example, a half-length patient or a stroke patient). The individual sign data is checked, and the user can also perform physical examination to relax the body, thereby improving the accuracy of the sign detection.

The above is only a preferred embodiment of the present invention, and is not intended to limit the scope of the invention, and the equivalent structure or equivalent function changes made by the description of the present invention and the contents of the drawings, or directly or indirectly applied to other related The technical field is equally included in the scope of patent protection of the present invention.

Industrial applicability

Claims

Claim

[Claim 1] A flat-bed type detecting device includes a monitoring table, a column plate, and a support frame, wherein one end of the monitoring table is provided with a head cover plate, and the head cover plate is provided with an infrared temperature sensing probe The infrared temperature sensing probe is used for sensing the temperature of the user's forehead as the user's body temperature data; the other end of the monitoring platform is fixed with a sliding rail on each side, and the sliding rail is disposed between the two sliding rails. a foot pedal is fixed on the sliding rod, and the foot pedal is provided with a pressure sensor, an infrared distance measuring sensor and a motor driver, wherein the motor driver is used to drive the sliding rod to slide along the sliding rail to make the The foot pedal is moved to a position of the user's feet lying flat on the monitoring platform, and the pressure sensor is configured to detect a pressure value of the user's feet contacting the foot pedal, the infrared The distance measuring sensor is configured to detect the distance between the foot pedal and the head cover as the user's height data when the pressure value is not zero

The monitoring station is further provided with an electronic weight scale for measuring the user's weight data; the column plate is provided with a microprocessor, and the outer surface of the column plate is embedded with a display screen, An arm sleeve and an electrocardiogram monitoring device are disposed on the column plate, the ECG monitoring device includes a 12-lead electrode and a lead wire, and the 12-lead electrode is connected to the microprocessor through a lead wire. The inner wall of the cavity of the arm sleeve is provided with a blood pressure sensor for detecting a blood pressure value of the user, the blood pressure sensor for detecting a pulse value of the user, and the microprocessor is used for The height data and the weight data are used to calculate the BMI index of the user, and the ECG signal is processed by the signal sampling process to obtain the user's electrocardiogram, and the BMI value, the electrocardiogram, the body temperature data, the blood pressure value, and the pulse value of the user are displayed in the On the display.

[Claim 2] The reclining sign detecting device according to claim 1, wherein one end of the column plate is provided with a concave port, and the monitoring table passes through the concave port and the column plate A fixed connection is used to support the monitoring station.

[Claim 3] The reclining sign detecting device according to claim 2, wherein the arm sleeve is fixed to one side edge of the concave opening, and the arm sleeve is an annular cavity structure The blood pressure sensor and the pulse sensor are disposed adjacent to an inner wall of the cavity of the arm sleeve.

[Claim 4] The lying type sign detecting device according to claim 1, wherein the twelve guide The joint electrode includes three limb lead electrodes, three pressurized lead electrodes and six chest lead electrodes

[Claim 5] The reclining body sign detecting apparatus according to claim 1, wherein the infrared temperature sensing probe is fixed to the head cover by an elbow, and the user lies in the monitoring On the stage, the infrared temperature probe is aligned with the forehead of the user by adjusting the direction and position of the bend to sense the temperature of the user's forehead.

[Claim 6] The reclining sign detecting device according to any one of claims 1 to 5, wherein the support frame is provided with a power switch and a communication interface, and the infrared temperature sensor and the electronic device A weight scale, a pressure sensor, an infrared range sensor, a motor drive, a display, a power switch, and a communication interface are all electrically coupled to the microprocessor.

[Claim 7] A flat rectal sign detecting method, which is applied to a flat reclining sign detecting device, the device comprising a monitoring table, a column plate and a support frame, wherein one end of the monitoring table is provided with a head cover The head cover is provided with an infrared temperature sensing probe, and a sliding rail is fixed on each side of the other end of the monitoring platform, and a sliding rod is disposed between the two sliding rails, and the sliding pedal is fixed on the sliding rod. The foot pedal is provided with a pressure sensor, an infrared distance measuring sensor and a motor driver. The column plate is provided with a microprocessor, the outer surface of the column plate is embedded with a display screen, and the column plate is provided with an arm sleeve. And an electrocardiogram monitoring device, the ECG monitoring device includes a 12-lead electrode and a lead wire, and the inner wall of the cavity of the arm sleeve is provided with a blood pressure sensor and a pulse sensor, wherein the flat-body sign detection method includes Step: when the power supply on the support frame is set, the motor driver drives the sliding rod to slide on the sliding rail of the monitoring platform along the direction of the user's feet; The pressure sensor detects a pressure value of a user's feet contacting the foot pedal; the microprocessor determines whether the pressure value is zero; when the pressure value is not zero, the micro The processor controls the motor driver to stop rotating to stop the sliding bar from sliding on the slide rail of the monitoring platform; the infrared ranging sensor detects a distance between the foot pedal and the head cover as a user Height data, the electronic weight scale measures user's weight data; the microprocessor calculates a user's BMI index based on the height data and body weight data; the twelve lead electrode collects a user's ECG signal And sending the collected ECG signals to the lead wire to the lead wire The microprocessor sends the ECG signal to the user's electrocardiogram through signal sampling processing; the infrared temperature sensing probe emits infrared light to sense the temperature of the user's forehead as the user's body temperature data; The blood pressure sensor detects a blood pressure value of the user, the pulse sensor detects a pulse value of the user; the microprocessor displays a BMI value, an electrocardiogram, a body temperature data, a blood pressure value, and a pulse value of the user on the display screen on. The method according to claim 7, wherein the method further comprises the step of: the microprocessor setting the BMI value, the electrocardiogram, the body temperature data, the blood pressure value, and the pulse value of the user in the The communication interface on the support frame is sent to the health management platform of the medical health center.

The method of detecting a lying sign of claim 7, wherein the step of the microprocessor to obtain the electrocardiogram of the user by signal sampling processing comprises the steps of: The ECG signal collected by the twelve-lead electrode is subjected to a chirp clock sampling process and a chirp clock conversion process to obtain a lead ECG waveform; the microprocessor converts the lead ECG waveform into a user's electrocardiogram.

The method for detecting a flat sign according to claim 7, wherein the infrared temperature probe is fixed on the head cover by a bent pipe, and when the user lies flat on the monitoring table, the Adjusting the direction and position of the elbow aligns the infrared temperature probe to the forehead of the user to sense the temperature of the user's forehead.