Shared electronic sphygmomanometer
Technical Field
The utility model relates to the field of electronic technology, especially, relate to a sharing type electrosphygmomanometer.
Background
The electronic sphygmomanometer is a medical device for measuring blood pressure by using modern electronic technology and an indirect blood pressure measuring principle. The electronic sphygmomanometer adopts a digital electronic measurement technology to monitor blood vessels of wrists or arms, and can complete high-precision real-time measurement of heart rate and blood pressure. The multifunctional pen has the characteristics of convenience in carrying, simplicity and convenience in operation, clear display, no need of much maintenance generally, and no need of beating and water sticking at ordinary times, and is very suitable for common families. The measurement mode of the commonly used electronic sphygmomanometer is an indirect mode, namely blood pressure and heartbeat numerical values are obtained by measuring through the wrist and the brachial artery and converting. Because the cuff is put on the wrist or the upper arm, the measurement stability of the cuff is superior to that of the traditional mercury column sphygmomanometer, and the cuff is more suitable for being used by patients with aging, arrhythmia, peripheral vascular aging caused by diabetes and the like.
At present, the electronic sphygmomanometer is a single-machine device as a blood pressure measurement medical device. The device can only work independently, and cannot perform data interaction with an intelligent terminal such as a mobile phone, a computer, a server and a cloud terminal. Therefore, the application of the traditional electronic sphygmomanometer in the current big data environment is greatly limited. In order to further expand the application function of the electronic sphygmomanometer, a wireless sharing function is expanded on the function of the traditional electronic sphygmomanometer. Namely, the electronic sphygmomanometer is wirelessly networked with intelligent terminals such as a mobile phone and a computer, so that the services of wireless control, data sharing and the like of blood pressure measurement can be realized.
SUMMERY OF THE UTILITY MODEL
In order to solve the technical problem, the utility model discloses a technical scheme be:
the utility model provides a sharing type electronic sphygmomanometer, including the host computer body, the trachea in sleeve area and connection host computer body and sleeve area, there is liquid crystal display, the keypad on the host computer body, bluetooth and WI-FI antenna, central controller's circuit board, including a motor, an end cap, a controller, and a cover plate, pneumatic pump, sensor and lithium cell group, its characterized in that, display screen and keypad are installed on host computer body panel, be furnished with central controller on the circuit board, bluetooth transceiver, WI-FI module and other peripheral auxiliary work circuit, the host computer body can realize the communication through bluetooth and WI-FI and host terminal.
Furthermore, the central controller may be a DSP, a single chip, or an embedded processor, and may communicate with an external computer through bluetooth or WI-FI, such as writing executable codes, configuration parameters, and the like.
Furthermore, parameters to be controlled can be input into the central controller through a keyboard or an upper terminal through Bluetooth or WI-FI, and then the motor and the air pressure pump are controlled.
Further, the liquid crystal display screen can be an LCD screen or an LED screen.
Furthermore, the liquid crystal display screen is an LCD screen or an LED screen for displaying the measured blood pressure and heartbeat value and all related parameters.
Furthermore, the voice module can broadcast the blood pressure and the heartbeat value obtained by measurement and all related parameters.
Further, the upper computer device comprises one or a combination of a smart phone, a mobile computer and a cloud server.
Furthermore, the measurement content and the parameter state can be wirelessly shared to upper terminal equipment such as a smart phone, a computer, a cloud server and the like through Bluetooth or WI-FI
Furthermore, after the measurement content and the parameters are shared to the upper terminal, the analysis of the measured data can be further realized, and the measurement content and the parameters can also be shared to a big data server for user data storage, individual feature analysis and data fusion monitoring.
Furthermore, the central controller is connected with the motor and the pneumatic pump.
Further, the pneumatic pump is connected with an air conduit.
Furthermore, the cuff is an annular closed cuff, and the diameter of the cuff is smaller than the outer diameter of a normal human arm.
Furthermore, the central controller is also connected with a voice module, so that data can be broadcasted in real time.
Specifically, the central controller receives instructions sent by a keyboard or instructions from the terminal machine transmitted through Bluetooth and WI-FI. According to the instruction, the central controller controls the motor to drive the pneumatic pump to press air into the conduit. Air is delivered to the cuff or wristband through the conduit to achieve pressurization of the blood vessel. In the process, the data of the sensor is collected by the central controller and is displayed on the liquid crystal screen in real time. The voice module simultaneously realizes the data broadcasting. In addition, the central controller transmits the acquired data to the upper terminal through Bluetooth and WI-FI, the upper terminal realizes data integration, and data can be further analyzed to realize data sharing.
Be different from prior art's condition, the beneficial effects of the utility model are that:
firstly, in a control mode, the purpose that an upper terminal sends an instruction to an electronic sphygmomanometer through Bluetooth and WI-FI is achieved, and wireless control is achieved. And the transmitted electronic sphygmomanometer can only send instructions through a keyboard on the device.
Secondly, in the aspect of data receiving and analyzing, the data can be transmitted back to the upper terminal through Bluetooth and WI-FI. The online accurate analysis of the data can be realized, and the data can be shared to the cloud service on a data platform so as to be stored and compared.
Drawings
Fig. 1 is a perspective view of a shared electronic sphygmomanometer according to an embodiment of the present invention.
Fig. 2 is a schematic view of data communication between the shared electronic sphygmomanometer according to an embodiment of the present invention and an upper terminal.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the embodiments of the present invention and the accompanying drawings, and obviously, the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
As shown in fig. 1, a shared electronic sphygmomanometer comprises a main body 1, a cuff 6 and an air tube 5 connecting the main body and the cuff, wherein the main body is provided with a liquid crystal display screen 2, a keyboard 3, a bluetooth and WI-FI antenna 4, a circuit board (not shown) including a central controller, a motor (not shown), an air pressure pump (not shown), a sensor (not shown) and a lithium battery pack (not shown). The display screen 2 and the keyboard 3 are arranged on a panel of the host body, a central controller, a Bluetooth transceiver, a WI-FI module and other peripheral auxiliary working circuits are arranged on the circuit board, and the host body can communicate with an upper terminal through Bluetooth and WI-FI.
Furthermore, the central controller may be a DSP, a single chip, or an embedded processor, and may communicate with an external computer through bluetooth or WI-FI, such as writing executable codes, configuration parameters, and the like.
Furthermore, parameters to be controlled can be input into the central controller through a keyboard or an upper terminal through Bluetooth or WI-FI, and then the motor and the air pressure pump are controlled.
Further, the liquid crystal display screen can be an LCD screen or an LED screen.
Furthermore, the liquid crystal display screen is an LCD screen or an LED screen for displaying the measured blood pressure and heartbeat value and all related parameters.
Furthermore, the voice module can broadcast the blood pressure and the heartbeat value obtained by measurement and all related parameters.
Further, the upper computer device comprises one or a combination of a smart phone, a mobile computer and a cloud server.
Furthermore, the measurement content and the parameter state can be wirelessly shared to upper terminal equipment such as a smart phone, a computer, a cloud server and the like through Bluetooth or WI-FI
Furthermore, after the measurement content and the parameters are shared to the upper terminal, the analysis of the measured data can be further realized, and the measurement content and the parameters can also be shared to a big data server for user data storage, individual feature analysis and data fusion monitoring.
Specifically, the central controller receives instructions sent by the keyboard or instructions from the terminal machine transmitted through Bluetooth or WI-FI. According to the instruction, the central controller controls the motor to drive the pneumatic pump to press air into the conduit. Air is delivered to the cuff or wristband through the conduit to achieve pressurization of the blood vessel. In the process, the data of the sensor is collected by the central controller and is displayed on the liquid crystal screen in real time. The voice module simultaneously realizes the data broadcasting. In addition, the central controller transmits the acquired data to the upper terminal through Bluetooth and WI-FI, the upper terminal realizes data integration, and data can be further analyzed to realize data sharing.
The above only is the embodiment of the present invention, not limiting the patent scope of the present invention, all utilize the equivalent structure or equivalent flow transformation that the content of the specification does, or directly or indirectly use in other related technical fields, all including in the same way the patent protection scope of the present invention.