CN211270705U - Health management terminal equipment - Google Patents

Abstract

The application discloses health management terminal equipment, which comprises a host and a slave, wherein the slave comprises a blood pressure monitoring circuit, a blood sugar monitoring circuit, a pedometer circuit, a respiration monitoring circuit and an artery electrocardiogram monitoring circuit, the blood pressure monitoring circuit, the blood sugar monitoring circuit, the pedometer circuit, the respiration monitoring circuit and the artery electrocardiogram monitoring circuit are all coupled with a sensor through a power amplifier circuit, and the blood pressure monitoring circuit, the blood sugar monitoring circuit, the pedometer circuit, the respiration monitoring circuit and the artery electrocardiogram monitoring circuit are all connected with a wireless transceiver module; the host comprises a wireless transceiver module, an analog-to-digital conversion circuit, an acquisition circuit, a processor and an upper computer communication circuit which are connected in series, wherein the wireless transceiver module of the host is electrically connected with the wireless transceiver module of the slave.

Description

Health management terminal equipment

Technical Field

The utility model relates to a mobile terminal, especially a health management terminal equipment.

Background

With the continuous improvement of living standard, people pay more and more attention to health care and routine examination. In addition, the aging of society is increasing, and the health problems of the elderly also become a problem of great social attention. Similar medical facilities on the market at present are large in size, inconvenient to carry, single in function or complex in operation. Is far from meeting the social demand. Therefore, it is imperative to develop a new medical device.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome the not enough of prior art, the utility model provides a technical scheme that its technical problem adopted is:

the utility model discloses a host computer and follow the computer, follow the computer and include blood pressure monitoring circuit, blood glucose monitoring circuit, pedometer circuit, breathe guardianship circuit, artery electrocardio guardianship circuit, blood pressure monitoring circuit, blood glucose monitoring circuit, pedometer circuit, breathe guardianship circuit, artery electrocardio guardianship circuit all couple the sensor through power amplifier circuit, blood pressure monitoring circuit, blood glucose monitoring circuit, pedometer circuit, breathe guardianship circuit, artery electrocardio guardianship circuit all connect wireless transceiver module; the host comprises a wireless transceiver module, an analog-to-digital conversion circuit, an acquisition circuit, a processor and an upper computer communication circuit which are connected in series, wherein the wireless transceiver module of the host is electrically connected with the wireless transceiver module of the slave.

Further, the wireless transceiver module is specifically a 2.4G wireless transceiver module.

Furthermore, the host also comprises a broadcasting circuit, an mp3 circuit and a calling circuit, and the broadcasting circuit, the mp3 circuit and the calling circuit are all connected with the control switch circuit and the processor.

Further, the processor adopts a field programmable gate array chip, the field programmable gate array chip is connected with the SDRAM card and the network card controller, and the network card controller is connected with an upper computer.

Furthermore, the acquisition circuit comprises a filtering function circuit, a current control function circuit and a coupling function circuit which are electrically connected in sequence.

The utility model has the advantages that:

through the utility model discloses a hardware architecture realizes following support at least:

the data collected by the host computer are sent to the server through the 3G network, and the server archives and analyzes the collected data, so that the following support is achieved: the doctor or the family can hold the user ID and the password, and use a mobile phone or a computer to connect with the server through the network to read the health condition information of the user. The broadcast circuit has FM broadcast receiving function, and the MP3 circuit MP3 playing function (a memory card is required to be inserted). The calling circuit has an emergency help-seeking function, when the emergency situation needs help seeking, a preset key of the host is pressed and is not released, the telephone is automatically dialed to the emergency contact person, and meanwhile, the short message is sent to the three emergency contact persons.

In addition, the processor adopts a field programmable gate array chip which is connected with the SDRAM card and a network card controller, and the network card controller is connected with an upper computer; the advantages of high efficiency, concurrent processing and low cost of the programmable gate array chip can be exerted.

Drawings

The present invention will be further explained with reference to the drawings and examples.

Fig. 1 is a block diagram of a circuit connection according to an embodiment of the present invention;

fig. 2 is a circuit connection block diagram of an embodiment of the host of the present invention;

fig. 3 is a block diagram of a circuit for connecting an embodiment of the processor of the present invention;

fig. 4 is a schematic circuit diagram of an embodiment of the acquisition circuit of the present invention.

Detailed Description

The technical solution of the present invention is described in detail with reference to the following specific embodiments, but the present invention is not limited thereto.

As shown in fig. 1, the utility model discloses a host computer and follow the machine, follow the machine and include blood pressure monitoring circuit, blood glucose monitoring circuit, meter step ware circuit, breathe monitoring circuit, artery electrocardio monitoring circuit, blood pressure monitoring circuit, blood glucose monitoring circuit, meter step ware circuit, breathe monitoring circuit, artery electrocardio monitoring circuit all connect the sensor through power amplifier circuit coupling, blood pressure monitoring circuit, blood glucose monitoring circuit, meter step ware circuit, breathe monitoring circuit, artery electrocardio monitoring circuit all connect wireless transceiver module; the host comprises a wireless transceiver module, an analog-to-digital conversion circuit, an acquisition circuit, a processor and an upper computer communication circuit which are connected in series, wherein the wireless transceiver module of the host is electrically connected with the wireless transceiver module of the slave; the slave computer is responsible for human physiological parameters: the main machine is responsible for collecting and uploading data, and can be set into modes such as real-time monitoring and regular uploading according to requirements; the upper computer in the upper computer communication circuit can be a server, data collected by the host computer are sent to the server through a 3G network, the server archives and analyzes the collected data, a doctor or a family can hold a user ID and a password, and the health condition information of the user is read by connecting the server through a network by using a mobile phone or a computer.

The wireless transceiver module is specifically a 2.4G wireless transceiver module.

As shown in fig. 2, the host further comprises a broadcasting circuit, an mp3 circuit and a calling circuit, and the broadcasting circuit, the mp3 circuit and the calling circuit are all connected with the control switch circuit and the processor; the broadcast circuit has FM broadcast receiving function, and the MP3 circuit MP3 playing function (a memory card is required to be inserted). The calling circuit has an emergency help-seeking function, when the emergency situation needs help seeking, a preset key of the host is pressed and is not released, the telephone is automatically dialed to the emergency contact person, and meanwhile, the short message is sent to the three emergency contact persons.

In the specific implementation, for convenience of implementation, the blood pressure monitoring circuit, the blood glucose monitoring circuit, the pedometer circuit, the respiratory monitoring circuit and the arterial electrocardiogram monitoring circuit can be replaced by the existing instruments, such as:

the slave machines are a sphygmomanometer (star 1), a blood glucose meter (star 1), a pedometer (star 1), a respiratory monitor (star 1) and an arterial electrocardiograph monitor (star 1).

Each slave machine has an independent 2.4G wireless transceiver module except for the measurement function of the slave machine.

The working mode is set when each slave machine leaves the factory,

the factory setting of the sphygmomanometer is a sleep mode, the internal part of the host is regularly reminded of 'measuring blood pressure' at 8 am every day, the sphygmomanometer is worn to start measurement at the moment, the measured data are stored in a sphygmomanometer memory after the measurement is finished, then the data are sent to the host through a 2.4G wireless module, and the host sends an instruction to the sphygmomanometer to enter the sleep mode after receiving the data.

If the sphygmomanometer does not receive the host response, the host is judged not to be in the receiving range, the measured data is placed in the area to be sent, and the measured data is sent to the host together when the host is connected next time. The sphygmomanometer enters a sleep state.

The blood glucose meter leaves the factory and is set to be in a sleep mode, the inside of the host computer is regularly reminded of measuring blood glucose at 8 am every day, the blood glucose meter is worn to start measurement at the moment, measurement data are stored in a memory of the blood glucose meter after the measurement is finished, then the data are sent to the host computer through a 2.4G wireless module, and the host computer sends an instruction to the blood glucose meter to enter the sleep mode after receiving the data.

If the blood glucose meter does not receive the host response, the host is judged not to be in the receiving range, the measured data is put into the area to be sent, and the measured data is sent to the host together when the host is connected next time. The glucose meter enters a sleep state.

The pedometer is set to be in a working state when leaving a factory, and data is sent to the host computer at regular time. And (3) regularly sending data to the host at 10 points, 14 points, 18 points and 20 points every day, if the host response is not received after the data is sent, judging that the host is not in a receiving range, putting the data into a to-be-sent area, and sending the data to the host when the data is sent next time. The wireless module is turned off.

The breathing monitor is factory-set to be in a sleep mode, the host prompts the breathing monitor to be worn (the time before sleep is set in the host) every night before sleep, the breathing monitor is worn and then sleeps, and the measurement data are uploaded every hour.

If the respiratory monitor does not receive the host response, the respiratory monitor judges that the host is not in the receiving range, and the measured data is put into the area to be sent and is sent to the host when the respiratory monitor is connected with the host next time. The wireless module is turned off. The respiratory monitor is manually turned off when getting up. The respiratory monitor has a wearing detection function, namely, the monitor does not carry out acquisition after being separated from a human body (or can be set to alarm after being separated through a host).

The arterial ECG monitor leaves factory and is set to be in a sleep mode, the host prompts the patient to wear the arterial ECG monitor (the time before sleep is set in the host) every night before sleep, the patient sleeps after wearing the arterial ECG monitor, and the measurement data is uploaded every hour.

If the arterial ECG monitor does not receive the response of the host, the host is judged not to be in the receiving range, the measured data is put into the area to be sent, and the measured data is sent to the host together when the host is connected next time. The wireless module is turned off. When getting up, the artery ECG monitor is manually closed. The artery ECG monitor has a wearing detection function, namely, the monitor is not collected after being separated from a human body (or can be set to alarm after being separated through a host).

As shown in fig. 3, the processor adopts a field programmable gate array chip, the field programmable gate array chip is connected with an SDRAM card and a network card controller, and the network card controller is connected with an upper computer; the advantages of high efficiency, concurrent processing and low cost of the programmable gate array chip can be exerted;

as shown in fig. 4, the acquisition circuit includes a filtering function circuit, a current control function circuit and a coupling function circuit, which are electrically connected in sequence; the filter function circuit a includes: an inductive element 1 and a transient diode 2. The first end of the inductance element 1 is connected with the in of the acquisition circuit and is connected with the signal of the sensor, the second end of the inductance element 1 is connected with the anode of the rectifying element 3, the cathode of the rectifying element 4 and the cathode of the transient diode 2 in the current control functional circuit b, and the anode of the transient diode 2 is grounded. The inductance element 1 is used for filtering interference of input alternating current, and the transient diode 2 is used for preventing the input transient voltage from being overhigh.

The current control function circuit b includes: rectifying element 3, rectifying element 4, current limiting element 5, current limiting element 6, bipolar transistor 10, current limiting element 9, indicator light 7, and current limiting element 8. The out of the filter function circuit a is connected with the anode of the rectifying element 3 and the cathode of the rectifying element 4, and is used for limiting the signal flow direction of the current control function circuit b, so that the signal passes through the rectifying element 3 and does not pass through the rectifying element 4. The negative pole of the rectifying element 3 is connected to a current limiting element 5 and a current limiting element 6, the current limiting element 5 is used for controlling the operating state of the bipolar transistor 10, the operating state can be a saturation state or a normal state, and the current limiting element 6 is used for limiting the current of the bipolar transistor 10. The negative electrode of the rectifying element 3 is connected to the collector of the bipolar transistor 10 and a first terminal of a current limiting element 9 via the current limiting element 5, and a second terminal of the current limiting element 9 is connected to the first isolation circuit. The current limiting element 9 is used to electrically isolate the output signal of the current control function circuit b in common with the coupling function circuit c. The negative electrode of the rectifying element 3 is connected to the base of the bipolar transistor 10 and the positive electrode of the indicator light 7 via the current limiting element 6. The cathode of the indicator light 7 is connected with the anode of the rectifying element 4 and the first end of the current limiting element 8, and the emitter stage of the bipolar transistor 10 is connected with the second end of the current limiting element 8 and the first isolating circuit.

The current control function circuit b is connected with the first isolation circuit through the current limiting element 9 and the emitter of the bipolar transistor 10, and outputs a digital signal through the isolation circuit. The emitter current of the bipolar transistor 10 in the current control function circuit b is the working current of the current control function circuit b, and the indicator light 7 and the current limiting element 8 form a current control circuit for controlling the emitter current of the bipolar transistor 10. The working current of the current control function circuit b is the quotient of the division of the input voltage U and the resistance R of the current limiting element 8, and can reach 20mA in practical application.

The coupling function circuit c includes: a first coupling element 11, a current limiting element 12. The primary in of the first coupling element 11 is connected with the current limiting element 9 in the current control function circuit b; the primary out of the first coupling element 11 is connected to the emitter of the bipolar transistor 10 in the current control function circuit b and to the current limiting element 8; the secondary in of the first coupling element 11 connects the current limiting element 12 and the out of the acquisition circuit; the secondary out of the first coupling element 11 is connected to ground. The current limiting element 12 is used to limit the current input to the primary side in of the coupling element 11, and prevent the current input to the coupling element 11 from being too large and reducing the service life of the coupling element. The coupling element 11 is used for electrically isolating the signal of the current control function circuit b and the output signal of the acquisition circuit. Alternatively, the withstand voltage and the switching speed of the coupling element 11 may be selected according to actual operating conditions. The coupling element 11 and the current limiting element 9 jointly form an isolation control circuit, and the isolation control circuit controls the on and off of the coupling element 11 by acquiring the voltage between the collector and the emitter of the bipolar transistor 10, so that digital signal acquisition is realized.

It will be appreciated by those skilled in the art that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The embodiments disclosed above are illustrative and not exclusive in all respects. All changes which come within the scope of the invention or which are equivalent to the scope of the invention are embraced by the invention.

Claims (5)

1. A health management terminal device is characterized by comprising a host and a slave, wherein the slave comprises a blood pressure monitoring circuit, a blood sugar monitoring circuit, a pedometer circuit, a respiration monitoring circuit and an artery electrocardio monitoring circuit, the blood pressure monitoring circuit, the blood sugar monitoring circuit, the pedometer circuit, the respiration monitoring circuit and the artery electrocardio monitoring circuit are all coupled with a sensor through a power amplifier circuit, and the blood pressure monitoring circuit, the blood sugar monitoring circuit, the pedometer circuit, the respiration monitoring circuit and the artery electrocardio monitoring circuit are all connected with a wireless transceiver module; the host comprises a wireless transceiver module, an analog-to-digital conversion circuit, an acquisition circuit, a processor and an upper computer communication circuit which are connected in series, wherein the wireless transceiver module of the host is electrically connected with the wireless transceiver module of the slave.

2. The health management terminal device according to claim 1, wherein the wireless transceiver module is a 2.4G wireless transceiver module.

3. The health management terminal device of claim 1, wherein the host further comprises a broadcast circuit, an mp3 circuit, and a call circuit, and the broadcast circuit, the mp3 circuit, and the call circuit are connected to the control switch circuit and the processor.

4. The health management terminal device according to claim 1, wherein the processor employs a field programmable gate array chip, the field programmable gate array chip is connected to the SDRAM card and the network card controller, and the network card controller is connected to the host computer.

5. The health management terminal device according to claim 1, wherein the collection circuit comprises a filter function circuit, a current control function circuit and a coupling function circuit electrically connected in sequence.

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