CN107315916B - Medical system based on two-dimensional code identity recognition and charging functions - Google Patents

Abstract

The invention provides a medical system based on two-dimension code identity recognition and charging functions, which comprises a self-service detection terminal with an MCU (micro control unit) single-chip microcomputer, wherein the self-service detection terminal is sequentially connected with a health server and a client, the MCU single-chip microcomputer is respectively connected with a data communication board, a blood pressure test module and a network communication module, and the data communication board is connected with a group of detection instruments. The data communication board is respectively connected with and controls the blood detector, the urine detector, the body temperature detector, the respiration detector, the electronic scale and the pedometer, and transmits test data of each detection instrument to the MCU singlechip, and the MCU singlechip carries out data processing, storage and display.

Description

Medical system based on two-dimensional code identity recognition and charging functions

Technical Field

The invention relates to the field of medical data management, in particular to a medical system based on two-dimensional code identity recognition and charging functions.

Background

In general routine examination in hospitals, the examination needs to be carried out under the guidance of doctors, a plurality of links such as registration, queuing, detection and the like are often needed, then medicine can be diagnosed, trouble is brought to most busy people, and the self-help examination is a trend of the medical industry.

The existing medical health management generally adopts a paper management mode, the recorded content is limited to the name, address and simple emergency knowledge of personnel, the information is very limited, and the information providing aspect of the personnel is very limited. Along with the gradual maturity of mobile internet technology and the wide popularization of smart phones, the intelligent mobile phone APP interaction is adopted to archive and collect information of health personnel, so that the accuracy and timeliness of paper document archiving are solved.

The common medical institutions adopt a manual charging mode, the labor cost occupies a large proportion in the expense of medical management, and the unmanned medical system charging mode becomes an important development direction of the medical industry.

Disclosure of Invention

The invention aims to: the invention aims to solve the technical problem of providing a medical system based on two-dimension code identity recognition and charging functions aiming at the defects of the prior art.

In order to solve the technical problems, the invention provides a medical system based on two-dimension code identity recognition and charging functions, which comprises a self-service detection terminal, a health server and a mobile phone APP client which are connected through data, wherein the self-service detection terminal comprises an MCU (micro control Unit) singlechip, the MCU singlechip is respectively connected with a data communication board, a display module and a network communication module, and the data communication board is connected with a group of detection instruments.

The mobile phone APP client comprises a two-dimension code scanning module, a user information registration module and a payment system, the health server comprises a user information storage module, a health data evaluation report module, an information pushing module, a hospital expert diagnosis system and a charging platform, a user downloads the user information registered by the mobile phone APP client in the user information registration module, the user information is stored in the user information storage module of the health server, the two-dimension code scanning module of the APP client scans the two-dimension code on the self-service detection terminal, reads the user information in the user information storage module, a user selects a detection item, the charging platform of the health server sends the charging information to the payment system of the mobile phone APP client, a signal is sent to the MCU singlechip of the self-service detection terminal after the payment is finished, the MCU singlechip sends the signal to control the corresponding detection instrument on the self-service detection terminal to be started, the measurement result is sent to the health server after the detection is finished, the health server stores the measurement result in the user information and sends the user information to the health data evaluation report module to generate a printing report, and the user can send the printing report to the hospital expert diagnosis system by adopting a TCP/IP mode through specified communication protocol.

In the invention, the data communication board is respectively connected with and controls the blood detector, the urine detector, the body temperature detector, the respiration detector, the electronic scale and the pedometer, and transmits the test data of each detection instrument to the MCU singlechip, and the MCU singlechip processes, stores and displays the data.

In the invention, the MCU singlechip is also connected with a liquid crystal display circuit, a power management circuit, an RFID radio frequency module, a loudspeaker circuit, a keyboard circuit and a data storage circuit.

In the invention, the data communication board comprises a 6-pin singlechip U15 and a 6-pin singlechip U16, wherein a second pin of the 6-pin singlechip U15 is connected with a resistor R16 and then is connected with a communication signal output end XTX, a fourth pin and a fifth pin of the 6-pin singlechip U15 are commonly connected with a resistor R17 and then are connected with a power supply, a first pin of the 6-pin singlechip U15 is respectively connected with a resistor R11, a thirteenth capacitor C13 and a communication signal input end RX, and the other end of the resistor R11 is connected with the power supply;

the first pin of the 6-pin singlechip U16 is connected with the communication signal input end after being connected with the resistor R17, the power supply is connected with the fourth pin and the fifth pin of the 6-pin singlechip U16 after being connected with the resistor R20, and the second pin of the 6-pin singlechip U16 is connected with the communication signal output end after being connected with the resistor R18.

In the invention, the loudspeaker circuit comprises a first active buzzer BEEP1, wherein the positive electrode of the first active buzzer BEEP1 is respectively connected with the positive electrodes of a third resistor R3 and a fourth capacitor C4, the other end of the third resistor R3 is connected with a power supply for adjusting the working current of the buzzer, the negative electrode of the fourth capacitor C4 is grounded and is used for providing stable working voltage for the buzzer, the negative electrode of the first active buzzer BEEP1 is connected with the collector electrode of a third triode Q3, and the collector electrode of the third triode Q3 is connected with a second resistor R2 and then connected with the BEEP_CTL pin of the singlechip.

In the invention, the network communication module comprises a first module U1, a second triode Q2, a fourth resistor R4, a ninth resistor R9, a thirteenth resistor R13, a fourteenth resistor R14, a first zener diode Z1, a seventh capacitor C7 and an eighth capacitor C8, wherein the second triode Q2, the fourth resistor R4, the ninth resistor R9, the thirteenth resistor R13 and the fourteenth resistor R14 form an ON-off circuit of the first module U1, and the POWER_ON pin of the MCU singlechip controls the ON-off of the network communication module U1; the VBAT pin of the first module U1 is connected to the negative electrode of the first zener diode Z1, the positive electrode of the eighth capacitor C8, and one end of the seventh capacitor C7, respectively, so as to provide a stable working voltage for the first module U1.

The self-service detection system comprises an RFID health card for storing user information, wherein the user information in the RFID health card is stored in a user information storage module in a health server, the mobile phone APP client comprises a two-dimension code scanning module, a user information registration module and a payment system, the health server comprises a user information storage module, a health data evaluation report module, an information pushing module, a hospital expert diagnosis system and a charging platform, the self-service detection terminal comprises an RFID card swiping area, the MCU singlechip is also connected with the RFID radio frequency module, the RFID health card is close to the RFID card swiping area, the RFID radio frequency module of the self-service detection terminal reads the user information in the user information storage module of the health server, a user selects a detection item, the charging platform of the health server sends the charging information to the payment system of the mobile phone APP client, the MCU singlechip after the payment is finished, the MCU singlechip sends a signal to control the start of a corresponding detection instrument on the self-service detection terminal, the health server sends a measurement result to the health server after the detection is finished, the health server stores the measurement result in a user information file and sends the user information file to the health data report to the health data evaluation report module through the information pushing module to the information printing module, and a communication report can be printed by a designated by a TCP/printing protocol, and the diagnosis system can be printed by the expert system.

In the invention, the RFID radio frequency module comprises an RFID radio frequency scanning module control circuit, the RFID radio frequency scanning module control circuit comprises a first field effect tube Q1, a first resistor R1, a fifth resistor R5, a sixth resistor R6, a seventh resistor R7, an eighth resistor R8, a fifteenth resistor R15, a twenty-fourth capacitor C24, a twenty-seventh capacitor C27 and a fortieth capacitor C40, the source electrode of the first field effect tube Q1 is respectively connected with a power supply and the fortieth capacitor C40, the other end of the fortieth capacitor C40 is grounded, the drain electrode of the first field effect tube Q1 is respectively connected with the power supply of the RFID radio frequency module, the twenty-fourth capacitor C24 and the twenty-seventh capacitor C27, the other ends of the twenty-fourth capacitor C24 and the twenty-seventh capacitor C27 are commonly grounded, and the grid electrode of the first field effect tube Q1 is connected with the first resistor R1 and then connected with the RF_CTL pin of the MCU;

one end of the fifteenth resistor R15 is connected with a reset pin of the RFID radio frequency module, the other end of the fifteenth resistor R15 is connected with a RST pin of the MCU singlechip, one ends of the fifth resistor R5, the sixth resistor R6, the seventh resistor R7 and the eighth resistor R8 are respectively connected with a communication port of the RFID radio frequency module, and the other ends of the fifth resistor R5, the sixth resistor R6, the seventh resistor R7 and the eighth resistor R8 are respectively connected with a communication port of the MCU singlechip.

In the invention, the MCU singlechip comprises an oscillating circuit consisting of a capacitor C2, a capacitor C3, a crystal oscillator X1 and a resistor R32, wherein a first pin of the MCU singlechip is connected with the capacitor C2 and then grounded, a second pin of the MCU singlechip is connected with the capacitor C3 and then grounded, and the crystal oscillator X1 and the resistor R32 are connected in parallel on the first pin and the second pin of the MCU singlechip;

the MCU singlechip comprises a reset circuit of an MCU composed of a resistor R30 and a capacitor C1, wherein the 59 th pin of the MCU singlechip is respectively connected with the resistor R30 and the capacitor C1, the other end of the resistor R30 is connected with a power supply, and the other end of the capacitor C1 is grounded;

the MCU singlechip comprises a stable detection circuit of the MCU singlechip formed by a temperature-sensitive resistor R22 and a high-precision resistor R23, wherein a 14 th pin of the MCU singlechip is connected with the temperature-sensitive resistor R22 and the high-precision resistor R23 in sequence and then connected with a power supply, and a 15 th pin of the MCU singlechip is connected with the high-precision resistor R23 and then grounded.

Through the APP customer end installed on the cell-phone, scan the two-dimensional code on the human basic disease self-service detection terminal, automatic identification user information, by user self-service selection detection project content, send charging unit to develop the work of charging deduction, the payment mode can have modes such as WeChat, payment treasured.

The beneficial effects are that: the basic information and the measurement result of the health personnel are stored in the network server in an operation mode, and the health information established by the user is connected with the medical database, so that doctors can conveniently and effectively master the basic information of the patients in time, and diagnosis and medical treatment can be better carried out.

The user can detect some own slow diseases in real time through the terminal and the self-help detection terminal for basic diseases of human bodies, links such as registration, queuing, window paying and the like are omitted, and the portable self-help detection terminal is portable and efficient.

Drawings

The foregoing and other advantages of the invention will become more apparent from the following detailed description of the invention when taken in conjunction with the accompanying drawings and detailed description.

Fig. 1 is a schematic diagram of a medical system structure based on two-dimensional code identity recognition and charging functions

Fig. 2 is an overall schematic block diagram of a self-help detection terminal for basic diseases of human body in an embodiment of the invention.

Fig. 3 is a schematic diagram of a circuit portion of a data communication board according to an embodiment of the present invention.

Fig. 4 is a schematic circuit diagram of a blood pressure measurement module according to an embodiment of the invention.

FIG. 5 is a schematic diagram of an inflator circuit and a bleeder circuit in blood pressure measurement according to an embodiment of the present invention.

Fig. 6 is a schematic circuit diagram of an MCU singlechip in an embodiment of the present invention.

Fig. 7 is a schematic circuit diagram of a loudspeaker according to an embodiment of the present invention.

Fig. 8 is a schematic circuit diagram of an RFID radio frequency scanning module according to an embodiment of the present invention.

Fig. 9 is a schematic circuit diagram of a network communication module according to an embodiment of the invention.

Detailed Description

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

Referring to fig. 1, after the mobile phone first scans the two-dimension code on the self-help detection terminal for basic diseases of human body and downloads and installs the APP client software, the APP client software transmits the registered health personnel information to the health server for archiving processing through the server network interface after registering the user related information on the mobile phone.

The two-dimension code scanning module is used for scanning the two-dimension code on the self-help detection terminal for basic diseases of human body, automatically downloading the APP client and reading the machine information of the detection terminal. The user information registration module establishes a personal health profile. The payment system is used for completing corresponding fees through WeChat, payment treasures, online banks and other payment systems according to medical detection items. The server network interface is used for carrying out network communication between the mobile phone APP client function and the health server, and transmitting all information and detection requirements of the user to the health server.

The intelligent mobile phone APP client comprises a two-dimension code scanning module, a charging module, a personal health information network management end and a self-help control human body basic disease detection terminal, wherein the personal health information network management end of the intelligent mobile phone APP client solves the timeliness and comprehensiveness of health personnel information, and comprises names, identification card numbers, contact modes, addresses, health states and the like; after the mobile phone APP client scans the two-dimensional code of the health information terminal, blood pressure detection, breath detection, blood detection, urine detection and body temperature detection can be performed; the mobile phone APP client carries health services, and the health network port can provide weather forecast information, a hospital expert system, travel guidelines, health service evaluation and advice, video diagnosis and the like.

The health server is a management system established with a designated medical institution or a corresponding management institution, manages the life health state of an individual, and the detection results of the self-help detection terminal for the personal basic diseases are automatically uploaded to the health server, stored, reserved, analyzed and information reminded, and each paid detection is operated on a charging platform of the health server, and all history files are stored in the health server for convenient inquiry and comparison at any time.

The health server provides a network interface between the mobile phone APP client and the health server, and a network interface between the health server and the personal basic disease self-help detection terminal. When a user requests to test a certain health item, the health item is selected on a mobile phone APP client and transmitted to a health server through a server network interface, after the health server compares user information and charging conditions, health content required to be requested by the user is transmitted to a personal basic disease self-service detection terminal through the network interface, and the personal basic disease self-service detection terminal measures according to the requested health item.

As shown in fig. 2, the invention discloses a self-help detection terminal for personal basic diseases, which consists of an MCU (micro control Unit) singlechip 1, a data communication board 2, a liquid crystal display circuit 3, a power management circuit 4, an RFID (radio frequency identification) radio frequency module 5, a loudspeaker circuit 6, a keyboard circuit 7, a data storage circuit 8, a network communication module 9, an antenna 10, a sphygmomanometer measurement module 11, a blood detector 12, a urine detector 13, a body temperature detector 14, a respiratory detector 15, an electronic scale 16, a pedometer 17, an arm belt 18, an inflator pump circuit 19 and an air release valve circuit 20. The blood pressure test module is used for detecting and collecting blood pressure. The network communication module is used for carrying out wireless communication with the network server.

The MCU singlechip is connected with the liquid crystal display circuit, the RFID sweep scanning module and the network communication module.

The MCU singlechip is connected with the blood pressure detection module and can be connected with equipment such as a blood detector, a urine detector, a body temperature detector, a respiration detector, an electronic scale, a pedometer and the like.

The network communication module is connected with the health server, and data of various measuring devices are transmitted to the health server through a network.

The liquid crystal display circuit adopts a microprocessor driven by a dot matrix display screen, and can directly display and read the data result of the test equipment.

The data communication board 2 is connected with various medical detection items of detecting instruments for controlling the detection and data acquisition of various detecting instruments, and the detecting instruments comprise a blood detector 12, a urine detector 13, a body temperature detector 14, a respiration detector 15, an electronic scale 16 and a pedometer 17.

The blood pressure test module 11 controls the inflation speed of the inflator circuit 19 and the air release valve circuit 20 through the armband 18 to detect and collect the intensity of human blood pulse, and transmits all data to the MCU singlechip 1.

The MCU singlechip 1 analyzes and processes all data and is connected with a data storage circuit 8, a liquid crystal display circuit 3, an RFID radio frequency module 5, a loudspeaker circuit 6, a key circuit 7 and a network communication module 9. The data storage circuit 8 stores and backs up data, the liquid crystal display circuit 3 controls liquid crystal display and displays the data on a screen, the RFID radio frequency module 5 detects and reads the data of an external health card or a citizen card, the loudspeaker circuit 6 prompts various test states by emitting sounds with various frequencies, the key circuit 7 is used for inquiring the data and can be used for emitting control commands to various external medical detection devices, and the network communication module 9 and the antenna 10 are connected with the health server in a wireless mode through a network interface protocol.

The power management circuit 4 provides various working voltages for all circuits of the whole personal basic disease self-service detection terminal so as to ensure the normal use of each component.

Referring to fig. 3, the data communication board includes a 6-pin single-chip microcomputer U15, a 6-pin single-chip microcomputer U16, a sixteenth resistor R16, a seventeenth resistor R17, an eighteenth resistor R18, a twentieth resistor R20, a fortieth-seventh resistor R47, an eleventh resistor R11, and a thirteenth capacitor C13. The pin 2 of the 6-pin singlechip U15 is connected with one end of a sixteenth resistor R16, and the other end of the sixteenth resistor R16 is connected with a communication signal output end and is used for limiting the current of signals; pins 4 and 5 of the 6-pin singlechip U15 are connected with one end of a seventeenth resistor R17, and the other end of the seventeenth resistor R17 is connected with a power supply and is used for pulling up communication signals; the pin 1 of the 6-pin singlechip U15 is respectively connected with one end of an eleventh resistor R11, one end of a thirteenth capacitor C13 and a communication signal input end, the other end of the thirteenth capacitor C13 is grounded and used for filtering high-frequency signals, and the other end of the eleventh resistor R11 is connected with a power supply and used for increasing the driving capability of communication signals. The pin 1 of the 6-pin singlechip U16 is connected with one end of a forty-seventh resistor R47, and the other end of the forty-seventh resistor R47 is connected with a communication signal input end for the current limiting function of signals; pins 4 and 5 of the 6-pin singlechip U16 are connected with one end of a twentieth resistor R20, and the other end of the twentieth resistor R20 is connected with a power supply for signal pull-up; and a pin 2 of the 6-pin singlechip U16 is connected with one end of an eighteenth resistor R18, and the other end of the eighteenth resistor R18 is connected with the output end of a communication signal.

The chips U15 and U16 adopt two IMX9 to switch the level between the two paths of communication signals, and the data communication board consists of the chips U15 and U16, resistors R11, R16, R17, R18, R20 and R47 and a capacitor C13. After the MCU singlechip outputs an XTX signal, the signal enters U15 through a current limiting resistor R16, the level of the RX signal is switched into the same working voltage of external detection equipment by a pull-up resistor R17, and the filtering of the high-frequency signal is carried out by C13; after the external detection equipment outputs a TX signal, U16 is carried out through a current limiting resistor R47, and the XRX signal level MCU singlechip needs working voltage.

The data communication board innovation advantage lies in being able to connect multiple check out test set, and the check out test set that can connect at present includes blood detector, urine detector, body temperature detector, breathe detector, electronic scale, pedometer, through the data communication board can control these equipment to with test data transmission to MCU singlechip, carry out data processing, storage and demonstration by the MCU singlechip.

As shown in fig. 4, the pressure sensor U2 is used in US9111-006 for detecting the intensity of the pulse signal of the human body, and the blood pressure measurement module is composed of the pressure sensor U2 and a resistor R31. After the pressure sensor U2 detects the pulse signals of the human body, analog signals are transmitted to the MCU singlechip through four pins of VI+, VI-, VO and VO-; the bias R31 adopts a high-precision resistor of 1% to provide stable bias voltage for the whole pressure sensor U2.

Referring to fig. 5, for the inflation pump circuit and the deflation valve circuit in the blood pressure measurement, the inflation pump BUMP1 is SC3701PMDC4.5V, the deflation valve FA1 is SC0526GLDC4.5V, and the inflation pump driving circuit is composed of triodes Q7 and Q9, resistors R12, R53 and R54, capacitors C9 and C19, and a diode D6. After the MCU singlechip outputs an X_PD0 signal, the triode Q7 and the triode Q9 are controlled to be conducted through the current limiting resistor R53 to supply power to the inflator pump, and the inflator pump is started to start working. The duty ratio of the X_DP0 pin is controlled to adjust the inflation speed of the inflator pump. The capacitors C9, C19 and diode D6 are placed for the purpose of providing a stable operating voltage to the overall system. Because the operating current of the charge pump is relatively large, a high-power transistor must be used for transistor Q9. The air release valve driving circuit is composed of a triode Q8, a resistor R55, a capacitor C53 and a diode D7. After the MCU singlechip outputs an X_PD1 signal, the triode Q8 is controlled to be conducted through the current limiting resistor R55 to supply power to the air release valve.

As shown in fig. 6, DC1001 is used as an MCU single chip. In the MCU singlechip circuit, a capacitor C2, a capacitor C3, a crystal oscillator X1 and a resistor R32 form an oscillating circuit of the MCU singlechip; the resistor R30 and the capacitor C1 form a reset circuit of the MCU; the temperature-sensitive resistor R22 and the high-precision resistor R23 form a stable detection circuit of the MCU singlechip, and are used for temperature compensation of data in blood pressure measurement. In this embodiment, the output end power_on of the MCU singlechip circuit is connected with the switch circuit of the network communication module, the serial port communication signal ports rx_gsm and tx_gsm of the MCU singlechip circuit are connected with the communication port of the network communication module, the input detection port vchg_int of the MCU singlechip circuit is connected with the POWER management circuit for POWER insertion detection function, the SPI communication signal port R, T, C, B of the MCU singlechip circuit is connected with the communication port of the RFID radio frequency module, the output end rf_ctl of the MCU singlechip circuit is used for controlling the POWER supply circuit of the RFID radio frequency module, the communication ports SCL and SDA of the MCU singlechip circuit are connected with the data storage circuit, the serial port communication signal ports XTX and XRX of the MCU singlechip circuit are connected with the network data communication board, the vo+, VO-, vi+, VI-of the MCU singlechip circuit are connected with the pressure sensor of the blood pressure measurement module, the output end gsm_ctl of the MCU singlechip circuit is connected with the POWER management circuit of the network communication module, the output end ep_ctl of the MCU singlechip circuit is connected with the loudspeaker circuit, and the COM line and SEG line of the MCU singlechip circuit are connected with the liquid crystal display circuit.

And when the blood pressure is measured, after the pulse pressure data of the human body is received, the MCU singlechip is internally provided with an operational amplifier circuit, the signal is amplified at the heart, and the signal is processed and analyzed by software through an algorithm, so that the blood pressure and the pulse data are measured.

As shown in fig. 7, the speaker circuit is composed of a transistor Q3, resistors R2 and R3, a capacitor C4, and a buzzer BEEP 1. The current limiting resistor R3 is used for adjusting the loudness of the buzzer, and the BEEP_CTL end of the MCU singlechip is used for controlling the opening and closing of the triode Q3, so that the switching effect of the buzzer is achieved.

The loudspeaker circuit comprises a first active buzzer BEEP1, a third resistor R3, a second resistor R2, a third triode Q3 and a fourth capacitor C4. The collector of the third triode Q3 is connected with the negative electrode of the first active buzzer BEEP1, the positive electrode of the first active buzzer BEEP1 is respectively connected with one end of the third resistor R3 and the positive electrode of the fourth capacitor C4, the negative electrode of the fourth capacitor C4 is grounded and used for providing stable working voltage for the buzzer, the other end of the third resistor R3 is connected with a power supply and used for adjusting working current of the buzzer, the collector of the third triode Q3 is connected with one end of the second resistor R2, the emitter is grounded, and the other end of the second resistor R2 is connected with the BEEP_CTL pin of the MCU singlechip and used for controlling the buzzer.

The loudspeaker circuit innovation has the advantages that the personal basic disease self-service detection terminal is judged to be in different states by emitting sounds with different frequencies, so that a user can use the terminal more intuitively and conveniently.

Referring to fig. 8, a schematic diagram of a communication control circuit of the rfid radio frequency scanning module is shown. The circuit is composed of resistors R5, R6, R7, R8, R15, R1, capacitors C24, C27, C40, a field effect transistor Q1 and an RFID radio frequency module GPM. The resistor R1, the capacitors C24, C27 and C40 and the field effect transistor Q1 form a power supply circuit of the scanning module, and the RF_CTL end of the MCU singlechip controls the on and off of the field effect transistor Q1, so that the on and off of a power supply are achieved, and the power saving effect is achieved. The current limiting resistors R5, R6, R7, R8 and R15 are connected in series in the communication data line, so that the radio frequency module and the MCU singlechip are more stable and reliable in communication.

The RFID radio frequency scanning module control circuit comprises a first field effect transistor Q1, a first resistor R1, a fifth resistor R5, a sixth resistor R6, a seventh resistor R7, an eighth resistor R8, a fifteenth resistor R15, a twenty-fourth capacitor C24, a twenty-seventh capacitor C27 and a forty capacitor C40. The source electrode of the first field effect transistor Q1 is connected with a power supply and one end of a fortieth capacitor C40; the other end of the forty capacitor C40 is grounded and used for power supply filtering; the drain electrode of the first field effect tube Q1 is connected with a power supply of the RFID radio frequency module, one ends of a twenty-fourth capacitor C24 and a twenty-seventh capacitor C27 are connected in parallel, and the other ends of the twenty-fourth capacitor C24 and the twenty-seventh capacitor C27 are grounded and used for power supply filtering; and the grid electrode of the first field effect tube Q1 is connected with one end of a first resistor R1, and the other end of the first resistor R1 is connected with an RF_CTL pin of the MCU singlechip and used for controlling the power supply of the RFID radio frequency module. One end of the fifteenth resistor R15 is connected with a reset pin of the RFID radio frequency module, and the other end of the fifteenth resistor R is connected with a RST pin of the MCU singlechip to control the reset of the RFID radio frequency module; one end of the fifth resistor R5, the sixth resistor R6, the seventh resistor R7 and the eighth resistor R8 are respectively connected with the communication port of the RFID radio frequency module, and the other end of the fifth resistor R5, the sixth resistor R6, the seventh resistor R7 and the eighth resistor R8 are respectively connected with the communication port of the MCU singlechip.

As shown in fig. 9, the network communication module adopts m660_gsm as the network communication module. In this embodiment, resistors R4, R9, R13, R14 and triode Q2 form a switching circuit of the network communication module, and are controlled by the power_on end of the MCU singlechip. In order to ensure the stability and reliability of the power supply, a zener diode Z1 and capacitors C7 and C8 are added to the power supply part of the network communication module. And the TX_GSM and RX_GSM of the network communication module are connected with the communication port of the MCU singlechip.

The network communication module comprises a first module U1, a second triode Q2, a fourth resistor R4, a ninth resistor R9, a thirteenth resistor R13, a fourteenth resistor R14, a first Zener diode Z1, a seventh capacitor C7 and an eighth capacitor C8. The second triode Q2, the fourth resistor R4, the ninth resistor R9, the thirteenth resistor R13 and the fourteenth resistor R14 form a startup and shutdown circuit of the network communication module U1, and the POWER_ON pin of the MCU singlechip controls the ON-off of the network communication module U1; the VBAT pin of the network communication module U1 is connected to the negative electrode of the first zener diode Z1, the positive electrode of the eighth capacitor C8, and one end of the seventh capacitor C7, respectively, so as to provide a stable working voltage for the module U1.

Embodiment one:

blood pressure measurement method 1: after the user scans the two-dimensional code on the personal basic disease self-help detection terminal, the mobile phone APP client can automatically read the machine information of the terminal, when the user selects blood pressure measurement, the APP client and the health server carry out communication to confirm the information of the user, the terminal and the payment condition, when the information is completely confirmed to be qualified, the health server sends a blood pressure measurement instruction to the personal basic disease self-help detection terminal, the terminal can automatically send a 'tic' sound, and meanwhile, a waiting blood pressure measurement is displayed on a liquid crystal screen. After the user binds the armband at the moment, the terminal can automatically start the inflator pump and the air release valve to measure the blood pressure by pressing a start/end button on the self-help detection terminal for the basic diseases of the individual. After the blood pressure measurement is finished, the measurement result is displayed on the liquid crystal screen and is sent to the health server, the health server stores the measurement result in the user information file, and the measurement result is forwarded to the mobile phone APP client.

Blood pressure measurement method 2: the user uses the RFID health card issued in advance (the health card needs to bind the user information and the card number together on the health server in advance), the RFID health card is swiped in a card swiping area on the personal basic disease self-help detection terminal, the terminal can automatically make a 'tic' sound, and meanwhile, the liquid crystal screen displays waiting for blood pressure measurement. After the user binds the armband at the moment, the terminal can automatically start the inflator pump and the air release valve to measure the blood pressure by pressing a start/end button on the self-help detection terminal for the basic diseases of the individual. After the blood pressure measurement is finished, the measurement result is displayed on the liquid crystal screen and is sent to the health server, the health server stores the measurement result in the user information file, and the measurement result is forwarded to the mobile phone APP client.

Embodiment two:

blood glucose measurement method 1: the blood glucose meter is inserted into the data port of the personal basic disease self-service detection terminal. After the user scans the two-dimensional code on the personal basic disease self-help detection terminal, the mobile phone APP client can automatically read the machine information of the terminal, when the user selects blood glucose measurement, the APP client and the health server carry out communication to confirm the information of the user, the terminal and the payment condition, when the information is completely confirmed to be qualified, the health server sends a blood pressure measurement instruction to the personal basic disease self-help detection terminal, the terminal can automatically send a 'tic' sound, and meanwhile, the liquid crystal screen displays waiting for blood glucose measurement. The user takes out a piece of test paper (disposable) from the blood sugar test paper box, inserts the test paper mouth of blood sugar detector, shows the blood sampling sign on the liquid crystal display screen this moment. The user places the blood taking needle (disposable) into the blood taking pen, disinfects the thumb which needs to take blood by alcohol sponge (disposable), drops certain metering blood to the test paper after taking blood by the blood taking pen, displays the blood sugar value on the terminal liquid crystal screen after a few seconds, sends the measurement result to the health server, and the health server stores the measurement result in the user information file and forwards the measurement result to the mobile phone APP client.

Blood glucose measurement method 2: the blood glucose meter is inserted into the data port of the personal basic disease self-service detection terminal. The user uses the RFID health card issued in advance (the health card needs to bind the user information and the card number together on the health server in advance), the RFID health card is swiped in a card swiping area on the personal basic disease self-help detection terminal, the terminal can automatically make a 'tic' sound, and meanwhile, the liquid crystal screen displays waiting for blood sugar measurement. The user takes out a piece of test paper (disposable) from the blood sugar test paper box, inserts the test paper mouth of blood sugar detector, shows the blood sampling sign on the liquid crystal display screen this moment. The user places the blood taking needle (disposable) into the blood taking pen, disinfects the thumb which needs to take blood by alcohol sponge (disposable), drops certain metering blood to the test paper after taking blood by the blood taking pen, displays the blood sugar value on the terminal liquid crystal screen after a few seconds, sends the measurement result to the health server, and the health server stores the measurement result in the user information file and forwards the measurement result to the mobile phone APP client.

When each item is checked, the information is automatically updated to the health server, the health server can transmit the information to the report module, the evaluation report is automatically generated, meanwhile, the measurement result data is stored in the server, a user can select to print the report at a computer end, can check the personal health report through a mobile phone APP, and can remotely access a personal health file network management end through the computer to check the personal health report.

The personal health file and the test data result are checked by individuals and the doctor checks the authority, so that the level difference of health personnel is ensured to be checked and managed by each medical institution.

The invention provides a medical system based on two-dimension code identity recognition and charging functions, and the method and the way for realizing the technical scheme are numerous, the above is only the preferred implementation mode of the invention, and it should be pointed out that a plurality of improvements and modifications can be made to those skilled in the art without departing from the principle of the invention, and the improvements and modifications are also regarded as the protection scope of the invention. The components not explicitly described in this embodiment can be implemented by using the prior art.

Claims (1)

1. The medical system based on the two-dimension code identity recognition and charging function is characterized by comprising a self-service detection terminal, a health server and a mobile phone APP client which are connected through data, wherein the self-service detection terminal comprises an MCU (micro control Unit) singlechip, the MCU singlechip is respectively connected with a data communication board, a display module and a network communication module, and the data communication board is connected with a group of detection instruments;

the mobile phone APP client comprises a two-dimension code scanning module, a user information registration module and a payment system, the health server comprises a user information storage module, a health data evaluation report module, an information pushing module, a hospital expert diagnosis system and a charging platform, the user downloads the mobile phone APP client to register user information in the user information registration module, the user information is stored in the user information storage module of the health server, the two-dimension code scanning module of the APP client scans the two-dimension code on the self-service detection terminal, reads the user information in the user information storage module, the user selects a detection item, the charging platform of the health server sends charging information to the payment system of the mobile phone APP client, a signal is sent to the MCU singlechip of the self-service detection terminal after the payment is finished, the MCU singlechip sends a signal to control the corresponding detection instrument on the self-service detection terminal to be started, after the detection is finished, the measurement result is sent to the health server, the health server stores the measurement result in a user information file and sends the user information to the health data evaluation report module to generate a printing report, and the printing report can be sent to the hospital expert diagnosis system by adopting a TCP/IP mode through a specified communication protocol;

the data communication board is respectively connected with and controls the blood detector, the urine detector, the body temperature detector, the respiration detector, the electronic scale and the pedometer, and transmits test data of each detection instrument to the MCU singlechip, and the MCU singlechip processes, stores and displays the test data;

the MCU singlechip is also connected with a liquid crystal display circuit, a power management circuit, an RFID radio frequency module, a loudspeaker circuit, a keyboard circuit and a data storage circuit;

the data communication board comprises a 6-pin singlechip U15 and a 6-pin singlechip U16, wherein a communication signal output end XTX is connected after a second pin of the 6-pin singlechip U15 is communicated with a resistor R16, a fourth pin and a fifth pin of the 6-pin singlechip U15 are commonly connected with a resistor R17 and then connected with a power supply, a first pin of the 6-pin singlechip U15 is respectively connected with a resistor R11, a thirteenth capacitor C13 and a communication signal input end RX, and the other end of the resistor R11 is connected with the power supply;

the first pin of the 6-pin singlechip U16 is connected with the resistor R17 and then connected with the communication signal input end, the fourth pin and the fifth pin of the 6-pin singlechip U16 are connected with the resistor R20 and then connected with the power supply, and the second pin of the 6-pin singlechip U16 is connected with the resistor R18 and then connected with the output end of the communication signal;

the loudspeaker circuit comprises a first active buzzer BEEP1, wherein the positive electrode of the first active buzzer BEEP1 is respectively connected with the positive electrodes of a third resistor R3 and a fourth capacitor C4, the other end of the third resistor R3 is connected with a power supply for adjusting the working current of the buzzer, the negative electrode of the fourth capacitor C4 is grounded and is used for providing stable working voltage for the buzzer, the negative electrode of the first active buzzer BEEP1 is connected with the collector electrode of a third triode Q3, and the collector electrode of the third triode Q3 is connected with a second resistor R2 and then connected with the BEEP_CTL pin of the singlechip;

the network communication module comprises a first module U1, a second triode Q2, a fourth resistor R4, a ninth resistor R9, a thirteenth resistor R13, a fourteenth resistor R14, a first Zener diode Z1, a seventh capacitor C7 and an eighth capacitor C8, wherein the second triode Q2, the fourth resistor R4, the ninth resistor R9, the thirteenth resistor R13 and the fourteenth resistor R14 form a switching circuit of the first module U1, and the POWER_ON pin of the MCU singlechip controls the switching of the network communication module U1; the VBAT pin of the first module U1 is respectively connected with the cathode of the first Zener diode Z1, the anode of the eighth capacitor C8 and one end of the seventh capacitor C7, and is used for providing stable working voltage for the first module U1; the system comprises an RFID health card for storing user information, wherein the user information in the RFID health card is stored in a user information storage module in a health server, the mobile phone APP client comprises a two-dimension code scanning module, a user information registration module and a payment system, the health server comprises a user information storage module, a health data evaluation report module, an information pushing module, a hospital expert diagnosis system and a charging platform, the self-service detection terminal comprises an RFID card swiping area, the MCU singlechip is also connected with the RFID radio frequency module, the RFID health card is close to the RFID card swiping area, the RFID radio frequency module of the self-service detection terminal reads the user information in the user information storage module of the health server, a user selects a detection item, the charging platform of the health server sends the charging information to the payment system of the mobile phone APP client, the MCU singlechip after the payment is finished, the MCU singlechip sends a signal to control the corresponding detection instrument on the self-service detection terminal to be started, after the detection is finished, the measurement result is sent to the health server, the health server stores the measurement result in the user information file and sends the user information file to the health data through the information pushing module to the health data evaluation report module to generate a communication report by adopting a TCP/printing protocol, and the diagnosis system can be printed by the expert printing system; the RFID radio frequency module comprises an RFID radio frequency scanning module control circuit, the RFID radio frequency scanning module control circuit comprises a first field effect transistor Q1, a first resistor R1, a fifth resistor R5, a sixth resistor R6, a seventh resistor R7, an eighth resistor R8, a fifteenth resistor R15, a twenty-fourth capacitor C24, a twenty-seventh capacitor C27 and a fortieth capacitor C40, a source electrode of the first field effect transistor Q1 is respectively connected with a power supply and the fortieth capacitor C40, the other end of the fortieth capacitor C40 is grounded, a drain electrode of the first field effect transistor Q1 is respectively connected with the power supply of the RFID radio frequency module, the twenty-fourth capacitor C24 and the twenty-seventh capacitor C27, the other ends of the twenty-fourth capacitor C24 and the twenty-seventh capacitor C27 are commonly grounded, and a grid electrode of the first field effect transistor Q1 is connected with an RF_CTL pin of the MCU after being connected with the first resistor R1;

one end of the fifteenth resistor R15 is connected with a reset pin of the RFID radio frequency module, the other end of the fifteenth resistor R15 is connected with a RST pin of the MCU singlechip, one ends of the fifth resistor R5, the sixth resistor R6, the seventh resistor R7 and the eighth resistor R8 are respectively connected with a communication port of the RFID radio frequency module, and the other ends of the fifth resistor R5, the sixth resistor R6, the seventh resistor R7 and the eighth resistor R8 are respectively connected with a communication port of the MCU singlechip;

the MCU singlechip comprises an oscillating circuit consisting of a capacitor C2, a capacitor C3, a crystal oscillator X1 and a resistor R32, wherein a first pin of the MCU singlechip is connected with the capacitor C2 and then grounded, a second pin of the MCU singlechip is connected with the capacitor C3 and then grounded, and the crystal oscillator X1 and the resistor R32 are connected in parallel with the first pin and the second pin of the MCU singlechip;

the MCU singlechip comprises a reset circuit of an MCU composed of a resistor R30 and a capacitor C1, wherein the 59 th pin of the MCU singlechip is respectively connected with the resistor R30 and the capacitor C1, the other end of the resistor R30 is connected with a power supply, and the other end of the capacitor C1 is grounded; the MCU singlechip comprises a stable detection circuit of the MCU singlechip formed by a temperature-sensitive resistor R22 and a high-precision resistor R23, wherein a 14 th pin of the MCU singlechip is connected with the temperature-sensitive resistor R22 and the high-precision resistor R23 in sequence and then connected with a power supply, and a 15 th pin of the MCU singlechip is connected with the high-precision resistor R23 and then grounded.