CN213696888U - Human health monitoring equipment and system - Google Patents

Abstract

The utility model provides a human health monitoring equipment and system, relates to electronic equipment technical field. Wherein human health monitoring equipment includes: a physiological index detection device configured to detect a physiological index of a human body; a processor; and a memory configured to store a detection result of the physiological index; the physiological index detection device is electrically connected with the processor through a first input/output interface of the processor, and the memory is electrically connected with the processor through a second input/output interface of the processor. Therefore, the physiological index detection device can conveniently detect the physiological index of the human body, and provide long-term human health monitoring data through the storage function of the memory, thereby realizing the human health monitoring equipment suitable for household use.

Description

Human health monitoring equipment and system

Technical Field

The present disclosure relates to the field of electronic devices, and in particular, to a human health monitoring device and system.

Background

With the development of social aging and the increasing pace of life, the health troubles suffered by some old people and middle-aged people with higher working pressure are increased. Some elderly diseases, such as hypertension, require long-term monitoring to guide clinical treatment. Some heart diseases require early detection for timely treatment.

SUMMERY OF THE UTILITY MODEL

The inventors have found that many people are not likely to go to the hospital frequently or in time for various reasons, and many diseases require long-term monitoring or early detection by people.

In view of this, the present disclosure provides a human health monitoring device suitable for home use, which can conveniently detect a physiological index of a human body through a physiological index detection device and provide long-term human health monitoring data through a storage function of a memory.

Some embodiments of the present disclosure provide a human health monitoring device, comprising:

a physiological index detection device configured to detect a physiological index of a human body;

a processor;

and

a memory configured to store a detection result of a physiological index;

the physiological index detection device is electrically connected with the processor through a first input/output interface of the processor, and the memory is electrically connected with the processor through a second input/output interface of the processor.

Optionally, the human health monitoring device further comprises: a control device configured to control the physiological index detection device; the control device is electrically connected with the processor through a third input/output interface of the processor.

Optionally, the physiological index detecting device includes: at least one detection unit of a blood pressure detection unit, a blood sugar detection unit, a blood oxygen detection unit, a heart rate detection unit, a heart rhythm detection unit and a body temperature detection unit; the control device includes control units corresponding to the respective detection units, wherein each control unit is configured to control the respective detection unit.

Optionally, the blood pressure detecting unit includes an air bag, an air pump, an exhaust valve, a pressure sensor and a blood pressure detecting and processing chip, wherein the air bag is connected with the air pump through an air pressure pipe, the exhaust valve is arranged on the air bag, the air pump, the exhaust valve and the pressure sensor are respectively connected with the blood pressure detecting and processing chip, and an output end of the blood pressure detecting and processing chip is electrically connected with the processor.

Optionally, the blood glucose detecting unit includes a blood glucose reading port and a blood glucose detecting and processing chip electrically connected to the blood glucose reading port, and an output end of the blood glucose detecting and processing chip is electrically connected to the processor.

Optionally, the blood oxygen detecting unit includes a reflector and a blood oxygen detecting and processing chip electrically connected to the reflector, and an output end of the blood oxygen detecting and processing chip is electrically connected to the processor.

Optionally, the heart rate detection unit includes heart rate detection bracelet and the heart rate detection processing chip of being connected with heart rate detection bracelet electricity, the output of heart rate detection processing chip with the treater electricity is connected.

Optionally, the heart rhythm detection unit includes an electrode plate, an electrocardiosignal acquisition and amplification module electrically connected to the electrode plate, and a heart rhythm detection processing chip electrically connected to the electrocardiosignal acquisition and amplification module, and an output end of the heart rhythm detection processing chip is electrically connected to the processor.

Optionally, the body temperature detecting unit includes a temperature sensor and a temperature processing chip electrically connected to the temperature sensor, and an output end of the temperature processing chip is electrically connected to the processor.

Optionally, the human health monitoring device further comprises: the physiotherapy device is configured to perform physiotherapy on a human body and is electrically connected with the processor through a fourth input and output interface of the processor, and the control device is further configured to control the physiotherapy device.

Optionally, the human health monitoring device further comprises: at least one of a data transmission interface, a wireless data transmission unit, and a network interface.

Optionally, the human health monitoring device further comprises: the emergency communication button is electrically connected with the processor through a fifth input/output interface of the processor; the processor is configured to trigger an audio alarm or trigger communication with a preset telephone number when the emergency communication button is pressed.

Optionally, the human health monitoring device further comprises: and the audio processing unit is electrically connected with the processor through a sixth input and output interface of the processor and is electrically connected with at least one of a microphone for audio input and a sound device for audio output.

Optionally, the human health monitoring device further comprises: a cabinet body of the bedside cabinet; wherein the physiological index detection device, the processor and the memory are located in the cabinet body.

Other embodiments of the present disclosure provide a human health monitoring system, including:

any one of the foregoing human health monitoring devices;

and

and the server is connected with the human health monitoring equipment.

Drawings

The drawings that will be used in the description of the embodiments or the related art will be briefly described below. The present disclosure will be more clearly understood from the following detailed description, which proceeds with reference to the accompanying drawings,

it is to be understood that the drawings in the following description are merely exemplary of the disclosure, and that other drawings may be derived from those drawings by one of ordinary skill in the art without undue inventive faculty.

Fig. 1 is a schematic structural view of some embodiments of the disclosed human health monitoring device.

Fig. 2 is a schematic view of a human health monitoring device in the form of a bedside table of the present disclosure.

Fig. 3 is a schematic view of a human health monitoring device in the form of a bedside table and its detection cabinet of the present disclosure.

Fig. 4 is a schematic structural diagram of some embodiments of the disclosed human health monitoring system.

Detailed Description

The technical solutions in the embodiments of the present disclosure will be clearly and completely described below with reference to the drawings in the embodiments of the present disclosure.

The terms "first", "second" … "sixth" and the like in the present disclosure are used only to distinguish different objects, and are not used to indicate the meaning of size, timing, and the like.

Fig. 1 is a schematic structural view of some embodiments of the disclosed human health monitoring device.

As shown in fig. 1, the human health monitoring device 10 includes: a physiological index detection device 110, a processor 120, and a memory 130.

The physiological index detecting device 110 is configured to detect a physiological index of a human body, such as blood pressure, blood sugar, blood oxygen, heart rate, heart rhythm, body temperature, etc., but not limited to these examples. The physiological index detection device 110 includes, for example: at least one of a blood pressure detection unit 111, a blood glucose detection unit 112, a blood oxygen detection unit 113, a heart rate detection unit 114, a heart rate detection unit 115, and a body temperature detection unit 116. Of course, the physiological index detecting device 110 may further include other detecting units corresponding to physiological indexes, which are not listed here.

These test units enable the user to obtain relatively comprehensive test results, and are very convenient to obtain, without going to a special medical institution.

The blood pressure detection unit 111 is configured to detect blood pressure, and includes, for example, an air bag, an air pump, an exhaust valve, a pressure sensor, and a blood pressure detection processing chip. The air bag is connected with the air pump through an air pressure pipe, the exhaust valve is arranged on the air bag, the air pump, the exhaust valve and the pressure sensor are respectively connected with the blood pressure detection processing chip, and the output end of the blood pressure detection processing chip is electrically connected with the processor 120. The pressure value detected by the pressure sensor is converted by the blood pressure detection processing chip, converted into a corresponding blood pressure value, then digitized by the analog-to-digital conversion unit 186, and transmitted to the processor 120.

The blood sugar detecting unit 112 is configured to detect blood sugar, and for example, includes a blood sugar reading port and a blood sugar detecting processing chip electrically connected to the blood sugar reading port, and an output end of the blood sugar detecting processing chip is electrically connected to the processor 120. The blood glucose card reader reads the data on the test paper, converts the data into corresponding blood glucose values through the conversion processing of the blood glucose detection processing chip, and then transmits the corresponding blood glucose values to the processor 120 through the digital processing of the analog-digital conversion unit 186.

Blood oxygen detection unit 113 is configured to detect blood oxygen, and for example includes a reflector and a blood oxygen detection processing chip electrically connected to the reflector, an output of the blood oxygen detection processing chip being electrically connected to processor 120. The data detected by the reflector is converted into corresponding blood oxygen value by the blood oxygen detection processing chip, and then is digitized by the analog-digital conversion unit 186 and transmitted to the processor 120.

The heart rate detection unit 114 is configured to detect a blood rate, and for example, includes a heart rate detection bracelet and a heart rate detection processing chip electrically connected to the heart rate detection bracelet, and an output of the heart rate detection processing chip is electrically connected to the processor 120. The heartbeat is detected by the heartbeat detection bracelet, and the corresponding heartbeat value is obtained through data processing such as timing and accumulation of the heartbeat detection processing chip, then is transmitted to the processor 120 through digital processing of the analog-digital conversion unit 186.

The heart rhythm detection unit 115 is configured to detect blood rhythms, and includes, for example, an electrode pad, an electrocardiographic signal acquisition and amplification module electrically connected to the electrode pad, and a heart rhythm detection processing chip electrically connected to the electrocardiographic signal acquisition and amplification module, an output end of the heart rhythm detection processing chip being electrically connected to the processor 120. The heart rhythm information output by the heart rhythm detection processing chip is digitized by the analog-to-digital conversion unit 186 and transmitted to the processor 120.

The body temperature detection unit 116 is configured to detect body temperature, and for example, includes a temperature sensor and a temperature processing chip electrically connected to the temperature sensor, and an output terminal of the temperature processing chip is electrically connected to the processor 120. The temperature information output by the temperature processing chip is digitized by the analog-to-digital conversion unit 186 and transmitted to the processor 120.

A processor 120 configured to receive the detection result of the physiological index from the physiological index detecting device 110 and store the result to the memory 130.

A memory 130 configured to store a detection result of the physiological index.

The physiological index detecting device 110 is electrically connected to the processor 120 through a first input/output interface 121 of the processor 120, and the memory 130 is electrically connected to the processor 120 through a second input/output interface 122 of the processor 120. The physiological index detection device 110 detects a physiological index of a human body and transmits a detection result of the physiological index to the processor 120, and the processor 120 stores the detection result of the physiological index in the memory 130

Therefore, the physiological index detection device can conveniently detect the physiological index of the human body, and provide long-term human health monitoring data through the storage function of the memory, thereby realizing the human health monitoring equipment suitable for household use.

As shown in fig. 1, the human health monitoring device further comprises: a control device 140 configured to control the physiological index detection device 110. The control device 140 is electrically connected to the processor 120 through the third input/output interface 123 of the processor 120.

In some embodiments, the control device 140 comprises control units corresponding to the respective detection units, each control unit being configured to control a respective detection unit. These control units include: a control unit 141 of the blood pressure detection unit 111, a control unit 142 of the blood glucose detection unit 112, a control unit 143 of the blood oxygen detection unit 113, a control unit 144 of the heart rate detection unit 114, and a control unit 145 of the heart rhythm detection unit 115.

These control units may be, for example, control buttons, which facilitate the user to directly control the detection units of the respective functions.

In other embodiments, the control function of the control device 140 for each detection unit can also be realized by touch control, that is, a touch control and display unit 147 is provided, which is connected to the processor 120 through a touch control and display driving unit 185. The user can perform a touch operation on the touch control and display unit 147, and control each detection unit by the touch operation, for example, control a certain detection unit to start detection or stop detection. The touch and display unit 147 may also display information of a detection state, a detection result, and the like.

The touch control and display unit 147 and the control units 141 to 145 are provided in one group, which can meet the control requirements, or can be arranged for the user to select and use. The control signals from the various forms of control device 140 are transmitted to the processor 120, and the processor 120 outputs corresponding control signals to corresponding detection units.

As shown in fig. 1, the human health monitoring device further comprises: a physiotherapy apparatus 150 configured to perform physiotherapy on the human body, and electrically connected to the processor 120 through the fourth input/output interface 124 of the processor 120. The control device 140 is also configured to control the physiotherapy device 150.

In some embodiments, the control unit 146 of the physiotherapy apparatus 150 is provided in the control apparatus 140, and may be in the form of an implementation of a control button, for example.

In other embodiments, a control function of the physiotherapy apparatus 150, for example, starting physiotherapy, stopping physiotherapy, or the like, is provided in the touch and display unit 147.

The touch control and display unit 147 and the control unit 146 may be combined to meet the control requirements of the physical therapy device, or may be combined to provide the user with the control requirements. The control signal from the touch and display unit 147 or the control unit 146 is transmitted to the processor 120, and the processor 120 outputs a corresponding control signal to a corresponding therapy apparatus.

The physiotherapy device 150 includes, for example, an oxygen generator or other electromagnetic or photoelectric physiotherapy device, etc., and is not limited to the illustrated examples.

As shown in fig. 1, the human health monitoring device further comprises: the emergency communication button 160 is electrically connected to the processor 120 through the fifth input/output interface 125 of the processor 120. A processor 120 configured to trigger an audio alert or trigger communication with a preset telephone number upon detecting the pressing of the emergency communication button 160.

The audio alarm can be implemented, for example, by a subsequent audio processing unit 170 and an audio device 172 for audio output. The alarm can be sent to the area near the family through audio alarm, so that the user can be rescued in time.

The communication with the preset telephone number may, for example, call a telephone number pre-stored in the storage unit 130 and communicate with the telephone number through the subsequent wireless data transmission unit 181. Thus, the user seeks help from 120 the emergency treatment center or relatives.

As shown in fig. 1, the human health monitoring device further comprises: and an audio processing unit 170 electrically connected to the processor 120 through the sixth input/output interface 126 of the processor 120, and electrically connected to at least one of a microphone 171 for audio input and a speaker 172 for audio output.

The user can input the voice description information of his/her health condition through the microphone 171, and the voice description information is processed by the audio processing unit 170 and then stored in the memory 130. Therefore, auxiliary description information of the human health condition is provided, and particularly detection contents which cannot be covered by the detection device, such as dizziness, chest distress and the like, are provided.

As shown in fig. 1, the human health monitoring device further comprises: at least one of a wireless data transmission unit 181, a data transmission interface 182, and a network interface 183. Among them, the data transmission interface 182 and the network interface 183 are connected to the processor 120 through the interface driving unit 184.

The information interaction with the outside can be realized in a wireless manner through the wireless data transmission unit 181. The information interaction with the outside can be realized in a wired manner through the network interface 183. The information interaction with the outside world includes, for example: uploading data to a server, communicating with a preset telephone number, or receiving health analysis data or health care guidance comments returned by the server, but not limited to the illustrated examples.

The detection result in the memory 130 can be imported into a mobile phone or other terminal equipment for viewing through the data transmission interface 182. The data transmission interface 182 may be a USB (Universal Serial Bus) interface, a Micro USB, a Mini USB, or other standard peripheral interfaces.

Furthermore, the human health monitoring device may further comprise: and the power supply 190 is used for supplying power to the human health monitoring equipment.

In addition, the human health monitoring device 10 may also be made in the form of a bedside table for convenient home placement and user use.

As shown in fig. 2, the human health monitoring device 10 further comprises: a cabinet 20. Some electronic components of the human health monitoring apparatus 10, such as the physiological index detecting device 110, the processor 120, the memory 130, the physiotherapy device 150, the audio processing unit 170, etc., may be disposed inside the cabinet 20.

The cabinet body 20 can be further divided into a detection cabinet 21 and a common cabinet 22 for daily use. The various electronic components of the human health monitoring device 10 enumerated above may be housed in the test cabinet 21. The conventional cabinet 22 may be made in the form of a drawer for placing daily articles, etc.

In addition, for convenience of handling, the control device 140 may be disposed outside the cabinet 20, for example. For example, respective detecting units in the form of buttons or control units 141 to 146 of the physiotherapy apparatus are provided at the boundary area of the upper surface and the front surface of the cabinet 20. The touch and display unit 147 may be disposed on the upper surface of the cabinet 20, and a recessed area may be further disposed on the upper surface so that the touch and display unit 147 can be embedded therein, placed and operated. A movable bracket may also be disposed in the recessed area, so that the touch and display unit 147 is supported to form a certain angle with the upper surface of the cabinet 20, which is convenient for a user to view and operate. In addition, the emergency communication button 160 may be, for example, an area on the side of the cabinet 20 for the user to press.

An exemplary arrangement of various electronic components of the human health monitoring device 10 in the detection cabinet 21 is shown in fig. 3, the detection cabinet 21 is provided with a plurality of partition boards, and a blood pressure detection unit 111, a heart rate detection unit 114, a blood glucose detection unit 112, a heart rhythm detection unit 115 and a physiotherapy device 150 (such as an oxygen generator) are sequentially arranged from top to bottom. It is obvious that other placement means can be used by those skilled in the art.

The present disclosure also provides a human health monitoring system.

As shown in fig. 4, the human health monitoring system 40 includes: a human health monitoring device 10; and a server 41 connected to the human health monitoring device 10. The human health monitoring device 10 may establish a communication connection with the server 41, for example, through the wireless data transmission unit 181 or the network interface 183.

As mentioned above, the human health monitoring device 10 may upload the detection data to the server, or receive the health analysis data or the medical care guidance from the server.

As shown in fig. 4, the human health monitoring system 40 further includes: a handset or other type of terminal device 42. The human health monitoring device 10 may establish a communication connection with the terminal device 42, for example, via the data transmission interface 182.

As previously mentioned, the human health monitoring device 10 may import the stored detection results to the terminal device 42.

The above description is only exemplary of the present disclosure and is not intended to limit the present disclosure, so that any modification, equivalent replacement, or improvement made within the spirit and principle of the present disclosure should be included in the scope of the present disclosure.

Claims (10)

1. A human health monitoring device, comprising:

a physiological index detection device configured to detect a physiological index of a human body;

the emergency communication button is electrically connected with the processor;

the wireless data transmission unit is electrically connected with the processor;

the processor is configured to trigger the wireless data transmission unit to communicate with a preset telephone number in a memory when the emergency communication button is detected to be pressed;

and

a memory configured to store a detection result of the physiological index and a phone number;

the physiological index detection device is electrically connected with the processor through a first input/output interface of the processor, and the memory is electrically connected with the processor through a second input/output interface of the processor.

2. The monitoring device of claim 1, further comprising:

a control device configured to control the physiological index detection device;

the control device is electrically connected with the processor through a third input/output interface of the processor.

3. The monitoring device of claim 2,

the physiological index detection device includes: at least one detection unit of a blood pressure detection unit, a blood sugar detection unit, a blood oxygen detection unit, a heart rate detection unit, a heart rhythm detection unit and a body temperature detection unit;

the control device includes control units corresponding to the respective detection units, wherein each control unit is configured to control the respective detection unit.

4. The monitoring device of claim 3,

the blood pressure detection unit comprises an air bag, an air pump, an exhaust valve, a pressure sensor and a blood pressure detection processing chip, wherein the air bag is connected with the air pump through an air pressure pipe, the exhaust valve is arranged on the air bag, the air pump, the exhaust valve and the pressure sensor are respectively connected with the blood pressure detection processing chip, and the output end of the blood pressure detection processing chip is electrically connected with the processor;

alternatively, the first and second electrodes may be,

the blood sugar detection unit comprises a blood sugar reading port and a blood sugar detection processing chip electrically connected with the blood sugar reading port, and the output end of the blood sugar detection processing chip is electrically connected with the processor;

alternatively, the first and second electrodes may be,

the blood oxygen detection unit comprises a reflector and a blood oxygen detection processing chip electrically connected with the reflector, and the output end of the blood oxygen detection processing chip is electrically connected with the processor;

alternatively, the first and second electrodes may be,

the heart rate detection unit comprises a heart rate detection bracelet and a heart rate detection processing chip electrically connected with the heart rate detection bracelet, and the output end of the heart rate detection processing chip is electrically connected with the processor;

alternatively, the first and second electrodes may be,

the heart rhythm detection unit comprises an electrode plate, an electrocardiosignal acquisition and amplification module electrically connected with the electrode plate and a heart rhythm detection processing chip electrically connected with the electrocardiosignal acquisition and amplification module, and the output end of the heart rhythm detection processing chip is electrically connected with the processor;

alternatively, the first and second electrodes may be,

the body temperature detection unit comprises a temperature sensor and a temperature processing chip electrically connected with the temperature sensor, and the output end of the temperature processing chip is electrically connected with the processor.

5. The monitoring device of claim 2, further comprising:

a physiotherapy device configured to perform physiotherapy on a human body and electrically connected with the processor through a fourth input/output interface of the processor,

the control device is also configured to control the physiotherapy device.

6. The monitoring device of any one of claims 1-5, further comprising: at least one of a data transmission interface and a network interface.

7. The monitoring device of any one of claims 1-5,

the processor is further configured to trigger an audio alert upon detecting the emergency communication button is pressed.

8. The monitoring device of any one of claims 1-5, further comprising:

and the audio processing unit is electrically connected with the processor through a sixth input and output interface of the processor and is electrically connected with at least one of a microphone for audio input and a sound device for audio output.

9. The monitoring device of any one of claims 1-5, further comprising:

a cabinet body of the bedside cabinet;

wherein the physiological index detection device, the processor and the memory are located in the cabinet body.

10. A human health monitoring system, comprising:

the human health monitoring device of any one of claims 1-9;

and

and the server is connected with the human health monitoring equipment.

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