CN217907789U - Physiological parameter acquisition electrocardiograph with wireless network - Google Patents
Physiological parameter acquisition electrocardiograph with wireless network Download PDFInfo
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- CN217907789U CN217907789U CN202121371719.8U CN202121371719U CN217907789U CN 217907789 U CN217907789 U CN 217907789U CN 202121371719 U CN202121371719 U CN 202121371719U CN 217907789 U CN217907789 U CN 217907789U
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Abstract
The physiological parameter acquisition electrocardiograph with the wireless network comprises an electrocardiograph body, wherein tpyec interfaces are arranged on at least one side face of the upper side and the lower side of the electrocardiograph body, an electrocardiograph interface is arranged on at least one side face of the left side and the right side of the electrocardiograph body, fixed bayonet clamps are arranged around the electrocardiograph interface, one of the front sides of the electrocardiograph body is a function output face, an LCD display screen for output is arranged in the middle of the function face, a function area is arranged on one side of the LCD display screen, a function key area is respectively arranged on the other side of the left side of the electrocardiograph body and at least one side of the upper side and the lower side of the electrocardiograph body, a camera, a light sensing hole, an upper loudspeaker groove, a lower loudspeaker groove and a display state LED lamp are sequentially arranged in the function area from top to bottom, an upper adjusting button, a lower adjusting button and a circular adjusting button are arranged on the key area, a chip for controlling the function area and the function button area are continuously powered by a built-in power supply. The utility model has the advantages of small volume, convenient use, simple operation, wide application range and the like.
Description
Technical Field
The patent of the utility model relates to a wireless network physiological parameter acquisition electrocardiograph belongs to medical treatment detection technology field.
Background
Before the heart beats, the cardiac muscle is excited first, and weak current is generated during excitation and is conducted to various parts through human tissues. Because the distance between each part of the body and the heart is different due to different tissues of each part, different potential changes are shown at each part of the body surface, and the relation between the surface potential generated by the electrical activity in the human heart and the time is called electrocardiogram. Electrocardiographs are instruments that record these physiological electrical signals. The electrocardiograph can automatically record the bioelectric signals (electrocardio signals) generated by exciting cardiac muscle during heart activity, and is a medical electronic instrument commonly used for clinical diagnosis and scientific research. Traditional electrocardiograph is because the setting of itself, has bulky, heavy, the consumption is big, carries inconveniently, complex operation, through a great deal of defects such as wired mode transmission data and application range are little (only use in the institute measure).
Disclosure of Invention
An object of the utility model is to provide a wireless network physiological parameter acquisition electrocardiograph that small, convenient to use easy operation and application range are wide. In order to achieve the purpose, the physiological parameter acquisition electrocardiograph with the wireless network comprises an electrocardiograph body, wherein tpye interfaces are arranged on at least one side face of the upper side and the lower side of the electrocardiograph body, electrocardiograph interfaces designed in parallel with the side faces are arranged on at least one side face of the left side and the right side of the electrocardiograph body, fixing bayonet clamps are arranged around the electrocardiograph interfaces, lead wires can be tightly fixed on the electrocardiograph interfaces and are not easy to pull out, one front face of the electrocardiograph body is a function output face, an LCD display screen for output is arranged in the middle of a function face, a function area is arranged on one side of the LCD display screen, function key areas are respectively arranged on the other side of the electrocardiograph body and at least one side of the upper side and the lower side of the electrocardiograph body, a camera, a light sensing hole, an upper loudspeaker groove, a lower loudspeaker groove and a display state LED lamp are sequentially arranged on the function area, an upper adjusting button, a lower adjusting button and a circular adjusting button are arranged on the button area, a chip for controlling the function area and the function button area are continuously powered by a built-in the electrocardiograph body.
Preferably, the method comprises the following steps: the chip is internally provided with a CPU main control unit, an MCU co-processing unit and an ECG integrated module unit, wherein one end of the ECG integrated module unit is externally provided with a electrocardio interface which can be used for connecting a lead wire, the other end of the ECG integrated module unit is connected with the MCU co-processing unit, the MCU co-processing unit is connected to a CPU main control board, the other end of the CPU main control board is connected to an LCD display screen, the other end of the CPU main control unit is connected to a key function area, the CPU main control unit, the MCU co-processing unit and the ECG integrated module unit are connected through an SPI (serial peripheral interface), power is supplied by a built-in power supply, data measured through the lead wire are converted into digital signals in the ECG integrated module unit, the digital signals are transmitted to the MCU co-processing unit for calculation and processing, then are transmitted to the CPU main control unit, the CPU main control unit displays the digital signals on the LCD display screen, and also can transmit instructions on the key function area to the CPU main control board, one end of which is co-processed by the MUC, and the other end of the CPU main control unit displays on the LCD display screen.
Preferably, the method comprises the following steps: the CPU main control unit is also provided with a tpye interface and a wireless output end, the tpye interface can transmit data to the PC end through the tpye or the wireless output end, and the built-in power supply can be charged through the tpye interface.
Preferably, the method comprises the following steps: the built-in power supply is a lithium battery fixed in the machine body or detachably installed in the machine body.
The utility model has the characteristics of it is following:
1. the electrocardio intelligent terminal equipment realizes data analysis at the equipment end;
2. a lead wire defibrillation function;
3. real-time dynamic storage and wireless transmission;
4. the portable electrocardiograph is suitable for real-time electrocardiographic detection inside and outside a hospital.
The utility model has the advantages of simple structure, convenient to carry makes convenient operation simple and application range extensively through wireless mode.
Drawings
Fig. 1 is a schematic structural diagram of the present invention.
Fig. 2 is a schematic view of fig. 1 taken along direction a.
Fig. 3 is a schematic block diagram of the present invention.
Detailed Description
The invention will be described in detail below with reference to the following drawings: as shown in fig. 1-3, a physiological parameter collecting electrocardiograph with wireless network comprises a body 1, wherein a tpyec interface 2 is arranged on at least one side surface of the upper and lower sides of the body 1, an electrocardiograph interface 3 designed in parallel with the side surface is arranged on at least one side surface of the left and right sides of the body 1, a fixed bayonet clip 4 is arranged around the electrocardiograph interface 3, a lead wire 5 can be tightly fixed on the electrocardiograph interface 3 and is not easy to pull out, one of the front surfaces of the body 1 is a function output surface 6, an LCD display 7 for output is arranged in the middle of the function surface 6, a function area 8 is arranged on one side of the LCD display 7, a function key area 9 is respectively arranged on the other side and at least one side of the upper and lower sides of the body 1, a camera 10, a light sensing hole 11, an upper horn slot 12, a lower horn slot 12 and a display state LED lamp 13 are sequentially arranged in the function area 8, an upper adjusting button 14 and a circular adjusting button 15 are arranged on the button area 9, a chip 16 for controlling the function area 8 and the function area 9 are further arranged in the body 1, and a power supply 20 is continuously arranged in the chip 16.
Preferably, the method comprises the following steps: the chip 16 is internally provided with a CPU main control unit 17, an MCU co-processing unit 18 and an ECG integrated module unit 19, wherein one end of the ECG integrated module unit 19 is externally provided with a cardiac electric interface 3 which can be used for connecting a lead wire 5, the other end of the ECG integrated module unit is connected with the MCU co-processing unit 18, the MCU co-processing unit 18 is connected to the CPU main control board 17, the other end of the CPU main control board 17 is connected to the LCD display screen 7, the other end of the CPU main control board is connected to the key function area 8, the CPU main control unit 17, the MCU co-processing unit 18 and the ECG integrated module unit 19 are connected through an SPI, power is supplied by an internal power supply 20, data measured through the lead wire are converted into digital signals in the ECG integrated module unit 19, the digital signals are transmitted to the MCU co-processing unit 18 for calculation and processing and then are transmitted to the CPU main control unit 21, the CPU main control unit 21 displays the digital signals on the LCD display screen 22, instructions on the key function area 9 can also be transmitted to the CPU main control board, one end of which is processed by the MUC, and the other end of the CPU main control board displays on the LCD display screen 21.
The CPU main control unit 21 is further provided with a tpye interface 22 and a wireless output terminal 23, the tpye interface 22 can transmit data to the PC terminal through a typec line and the wireless module output terminal 23, and can charge the built-in power supply 20 through the tpye interface 22.
The utility model discloses wherein power module is detailed as follows:
CPU main control unit
Controlling the power supply of the signal acquisition unit; controlling storage of user data; controlling the display of an LCD or an LCD display screen, and reading the touch input of a user; controlling the connection of the WiFi module and other equipment; controlling the connection of the 4G module and other equipment; collecting input of a function key; controlling an LED indicator light and a buzzer; and controlling the connection between the TypeC and the PC end.
And MCU co-processing.
And acquiring the electrocardiogram data of the ECG integrated module through the SPI, and uploading the data to the CPU main control through the other SPI. And detecting the lead insertion state.
ECG integrated module
Is responsible for electrocardio acquisition, filtering, lead connection and drop monitoring. The electrocardio analog signal is converted into a digital signal through an internal ADC;
an external interface.
A Type power supply charging interface;
and charging the equipment through the Type C interface, and carrying out data communication with the PC terminal.
ECG lead wire
Collect human bioelectricity, and integrate the defibrillation protection circuit. The built-in power supply is a lithium battery fixed in the machine body or detachably installed in the machine body.
The utility model discloses a concrete operation process as follows:
1) Starting up, logging in an APP;
2) 12-lead electrocardiographic waveform display, a suction ball and a clip of a lead wire are worn on the chest and the limbs;
3) The electrocardio is collected, stored in real time and transmitted to the platform in a wireless way;
4) And performing real-time analysis at the platform end.
The utility model has the characteristics of it is following:
1) The electrocardio intelligent terminal equipment realizes data analysis at the equipment end;
2) A lead wire defibrillation function;
3) Real-time dynamic storage and wireless transmission;
4) The portable electrocardiograph is suitable for real-time electrocardiographic detection inside and outside a hospital.
The above description is only a preferred embodiment of the present invention, and the present invention is not limited to the above embodiment, and all that is required is that the technical effects are achieved by the same means, and the present invention is within the protection scope of the present invention. The technical solution and/or the embodiments of the invention may be subject to various modifications and variations within the scope of the invention.
Claims (4)
1. The utility model provides a take wireless network's physiological parameter acquisition electrocardiograph, it includes organism body, its characterized in that: the portable multifunctional heart-fire monitor is characterized in that tpyec interfaces are arranged on at least one side face of the upper portion and the lower portion of the main body, an electrocardio interface which is designed in parallel with the side face is arranged on at least one side face of the left portion and the right portion of the right portion, fixed bayonet clamps are arranged on the periphery of the electrocardio interface, lead wires can be tightly fixed on the electrocardio interface and cannot be easily pulled out, one front face of the main body is a function output face, an LCD display screen for output is arranged in the middle of the function face, a function area is arranged on one side of the LCD display screen, function button areas are arranged on the other side of the main body and on at least one side of the upper portion and the lower portion of the main body respectively, a camera, a light sensing hole, an upper loudspeaker groove, a lower loudspeaker groove and a display state LED lamp are sequentially arranged on the function area from top to bottom, an upper adjusting button area, a lower adjusting button and a round adjusting button area are arranged in the main body, and a chip for controlling the function button area is further arranged in the main body and continuously powered by a built-in power supply.
2. The physiological parameter acquisition electrocardiograph with a wireless network according to claim 1, wherein: the chip is internally provided with a CPU main control unit, an MCU assistant processing unit and an ECG integrated module unit, wherein one end of the ECG integrated module unit is externally provided with an electrocardio interface which can be used for connecting a lead wire, the other end of the ECG integrated module unit is connected with the MCU assistant processing unit, the MCU assistant processing unit is connected to a CPU main control board, the other end of the CPU main control board is connected to an LCD display screen, the other end of the CPU main control unit is connected to a key function area, the CPU main control unit, the MCU assistant processing unit and the ECG integrated module unit are connected through an SPI, power is supplied by a built-in power supply, data measured through the lead wire is converted into digital signals in the ECG integrated module unit, the digital signals are transmitted to the MCU assistant processing unit for calculation and processing, then are transmitted to the CPU main control unit, the CPU main control unit displays the digital signals on the LCD display screen, and also can transmit instructions on the key function area to one end of the CPU main control board for MUC assistant processing, and the other end of the CPU main control unit displays on the LCD display screen.
3. The physiological parameter acquisition electrocardiograph with a wireless network according to claim 2, wherein: the CPU main control unit is also provided with a tpye interface and a wireless module output end, the tpye interface can transmit data to the PC end through the tpye or a wireless transmission output end, and the built-in power supply can be charged through the tpye interface.
4. The physiological parameter acquisition electrocardiograph with wireless network according to claim 1, 2 or 3, wherein: the built-in power supply is a lithium battery fixed in the machine body or detachably installed in the machine body.
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| Application Number | Priority Date | Filing Date | Title |
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| CN202121371719.8U CN217907789U (en) | 2021-06-21 | 2021-06-21 | Physiological parameter acquisition electrocardiograph with wireless network |
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| CN202121371719.8U CN217907789U (en) | 2021-06-21 | 2021-06-21 | Physiological parameter acquisition electrocardiograph with wireless network |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN113413160A (en) * | 2021-06-21 | 2021-09-21 | 浙江好络维医疗技术有限公司 | Physiological parameter acquisition electrocardiograph with wireless network |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN113413160A (en) * | 2021-06-21 | 2021-09-21 | 浙江好络维医疗技术有限公司 | Physiological parameter acquisition electrocardiograph with wireless network |
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