CN221690986U - External defibrillator ECG monitoring device - Google Patents

Abstract

The utility model discloses an electrocardiograph monitoring device of an external defibrillator, which relates to the technical field of electrocardiograph monitoring, wherein a device main body is connected with a conductor, and the conductor is connected with an electrocardiograph electrode; the device is characterized in that a microprocessor is arranged inside the device main body and is connected with an electrocardiograph collector and an electrocardiograph analyzer, a Bluetooth connector is arranged at the bottom of the microprocessor and is connected with the bottom of the device main body, an alarm is arranged on the front side of the device main body, and the alarm is connected with the microprocessor. Because the setting of electrocardio electrode and conductor can make the user when wearing, connect a plurality of electrocardio electrodes through the conductor, when the conductor with heart rate data transmission to electrocardio collector and electrocardio analyzer, can be according to array data contrast to discharge the inside murmur of human body, make this equipment more accurate when detecting the heart rate, and through microprocessor's setting, thereby can calculate array data and transmit to the automatic external defibrillator body inside from bluetooth connector.

Description

External defibrillator ECG monitoring device

Technical Field

The utility model relates to the technical field of electrocardiogram monitoring, in particular to an electrocardiogram monitoring device for an external defibrillator.

Background Art

ECG monitoring is a means of monitoring the electrical activity of the heart. Ordinary ECG can only simply observe the short-term ECG activity of the heart when the ECG is recorded. ECG monitoring is a non-invasive monitoring method that continuously monitors the electrical activity of the heart through a display screen. It can timely observe the condition, provide reliable and valuable ECG activity indicators, and guide real-time processing. Therefore, it has important use value for patients with abnormal ECG activity, such as acute myocardial infarction, various arrhythmias, etc. In the work of automatic external defibrillators, ECG monitoring devices are often required to detect the patient's heart rate in order to better enable the external defibrillator to work. However, the existing ECG monitoring devices for external defibrillators have some shortcomings, such as:

Publication No.: CN103357113A Backpack-type automatic external defibrillator with remote positioning monitoring function, the device is composed of ECG collection electrodes, defibrillation electrodes, a fixing device for fixing on the human body, and a cable for connecting the backpack and the defibrillation host; the defibrillation electrodes contain an automatic gel spraying device, so as to perform defibrillation monitoring on the user; however, in actual use, when the ECG collection electrodes collect the heart rate inside the human body, the internal noise of the human body will affect the ECG collection electrodes to collect the heart rate, which may cause the device to monitor the user's heart rate.

Therefore, we propose an external defibrillator ECG monitoring device to solve the above-mentioned problems.

Utility Model Content

The utility model aims to provide an external defibrillator ECG monitoring device to solve the problem raised in the above background technology that when the ECG collecting electrodes of the existing ECG monitoring device collect the heart rate inside the human body, the noise inside the human body will affect the ECG collecting electrodes to collect the heart rate, which may cause the device to have monitoring data errors when monitoring the user's heart rate.

To achieve the above-mentioned purpose, the utility model provides the following technical solutions: an external defibrillator ECG monitoring device, comprising a device body, a conductor connected to the device body and an automatic external defibrillator body, the device body is connected to the conductor, and the conductor is connected to the ECG electrode;

A microprocessor is provided inside the device body, and the microprocessor is connected to the ECG collector and the ECG analyzer. A Bluetooth connector is provided at the bottom of the microprocessor, and the Bluetooth connector is connected to the bottom of the device body. An alarm is provided on the front side of the device body, and the alarm is connected to the microprocessor.

Due to the setting of the ECG electrodes and the conductor, the user can connect multiple ECG electrodes through the conductor when wearing the device. When the conductor transmits the heart rate data to the ECG collector and the ECG analyzer, the data can be compared based on the array data, thereby eliminating the noise inside the human body, making the device more accurate in detecting the heart rate. Moreover, through the setting of the microprocessor, the array data can be calculated and transmitted from the Bluetooth connector to the inside of the automatic external defibrillator body, making the automatic external defibrillator body easier to adjust when performing defibrillation on the wearer.

As a preferred technical solution of the utility model, a display and an integrated control panel are provided on the front side of the device body, and the display and the integrated control panel are connected to a microprocessor.

The adoption of the above technical solution can make it more convenient for users to observe the wearer's heart rate data, and the efficiency of shielding noise can be adjusted through the integrated control panel.

As a preferred technical solution of the present utility model, a power supply is provided inside the device body, and the power supply can be connected to the microprocessor.

The adoption of the above technical solution enables the device to continue working even without power support, thereby increasing the convenience of the device when in use.

As a preferred technical solution of the utility model, the microprocessor is wired to the recorder, and the recorder can input the stored data into the Bluetooth connector.

The above technical solution enables the recorder to record the data processed by the microprocessor when the wearer wears the device, thereby better storing the data. When the user checks the usage of the device, the device inside the recorder can be called up for operation.

As a preferred technical solution of the present utility model, a fixer is provided on the outside of the device body, and the fixer is connected to the device body.

The adoption of the above technical solution can make it more convenient for the wearer to wear the device, thereby increasing the convenience of the device when worn.

As a preferred technical solution of the utility model, the microprocessor inside the device body transmits data to the automatic external defibrillator body through the Bluetooth connector, and the Bluetooth connector can be connected to the automatic external defibrillator body.

The adoption of the above technical solution enables the Bluetooth connector to automatically match the automatic external defibrillator body through remote signals, thereby increasing the convenience of the device when connecting with the automatic external defibrillator body or other devices.

As a preferred technical solution of the utility model, a connecting wire is provided on the top of the device body, and the device body is connected to the conductor through the connecting wire, and the conductor is connected to the ECG electrode through the conducting wire, and the inner side of the ECG electrode has a certain degree of stickiness.

The above technical solution enables the conductor to be connected to multiple ECG electrodes through the conducting wires, so that the data of the multiple ECG electrodes can be transmitted from the conductor to the inside of the microprocessor.

Compared with the prior art, the beneficial effects of the utility model are:

1. Due to the setting of ECG electrodes and conductors, when the user wears the device, the conductor can connect multiple ECG electrodes. When the conductor transmits the heart rate data to the ECG collector and the ECG analyzer, the data can be compared based on the array data, thereby eliminating the noise inside the human body, making the device more accurate in detecting the heart rate. Moreover, through the setting of the microprocessor, the array data can be calculated and transmitted from the Bluetooth connector to the inside of the automatic external defibrillator body, making the automatic external defibrillator body easier to adjust when performing defibrillation on the wearer;

2. Through the setting of the display and the integrated control panel, the user can observe the wearer's heart rate data more conveniently, and the integrated control panel can be used to adjust the efficiency when noise needs to be shielded. And through the setting of the power supply, the device can continue to work without power support, which increases the convenience of the device when used.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of a front cross-sectional structure of the utility model;

FIG2 is a front view of the structure of the present utility model;

FIG3 is a schematic diagram of the elevation structure of the utility model;

FIG4 is a schematic diagram of the main structure of the frame of the present invention;

FIG. 5 is a schematic diagram of the main operation flow structure of the utility model.

In the figure: 100, device body; 101, microprocessor; 102, ECG collector; 103, ECG analyzer; 104, Bluetooth connector; 105, recorder; 106, display; 107, integrated control board; 108, alarm; 109, power supply; 110, holder; 201, conductor; 202, ECG electrode; 203, connecting line; 204, conducting line; 300, automatic external defibrillator body.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments in the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Referring to FIGS. 1-5 , the utility model provides a technical solution: an external defibrillator ECG monitoring device, comprising a device body 100, a conductor 201 connected to the device body 100, and an automatic external defibrillator body 300, wherein the device body 100 is connected to the conductor 201, and the conductor 201 is connected to the ECG electrode 202;

A microprocessor 101 is provided inside the device body 100, and the microprocessor 101 is connected to an electrocardiogram collector 102 and an electrocardiogram analyzer 103, and a Bluetooth connector 104 is provided at the bottom of the microprocessor 101, and the Bluetooth connector 104 is connected to the bottom of the device body 100, and an alarm 108 is provided at the front side of the device body 100, and the alarm 108 is connected to the microprocessor 101;

When using the external defibrillator ECG monitoring device, first connect the ECG electrode 202 to the chest or abdomen of the wearer, then start the microprocessor 101, then the ECG electrode 202 will transmit the wearer's heart rate data to the conductor 201, and the conductor 201 will transmit the data to the ECG collector 102 inside the device body 100, then the ECG collector 102 will transmit the data to the microprocessor 101, and the microprocessor 101 will process the data through the ECG analyzer 103 and then perform When the data shows abnormality, the alarm is sent out through the alarm 108. When the data does not show abnormality, the microprocessor 101 transmits the data to the Bluetooth connector 104. At this time, the Bluetooth connector 104 searches for the automatic external defibrillator body 300 through the remote signal. When the signal of the automatic external defibrillator body 300 is not detected, the Bluetooth connector 104 sends out an alarm through the alarm 108. When the signal is detected, the Bluetooth connector 104 transmits the data to the automatic external defibrillator body 300.

The front side of the device body 100 is provided with a display 106 and an integrated control board 107, and the display 106 and the integrated control board 107 are connected to the microprocessor 101; the inside of the device body 100 is provided with a power supply 109, and the power supply 109 can be connected to the microprocessor 101; the microprocessor 101 is wired with the recorder 105, and the recorder 105 can input the stored data into the Bluetooth connector 104; the outside of the device body 100 is provided with a holder 110, and the holder 110 is connected to the device body 101. 0; the microprocessor 101 inside the device body 100 transmits data to the automatic external defibrillator body 300 through the Bluetooth connector 104, and the Bluetooth connector 104 can be connected to the automatic external defibrillator body 300; a connecting line 203 is provided on the top of the device body 100, and the device body 100 is connected to the conductor 201 through the connecting line 203, and the conductor 201 is connected to the ECG electrode 202 through the conducting line 204, and the inner side of the ECG electrode 202 has a certain degree of stickiness;

When the user wants to connect multiple ECG electrodes 202, they can be connected to the conductor 201 through the conductive wire 204, and the microprocessor 101 will transmit the data to the recorder 105 after processing the data, so as to record the working conditions of the device when it is worn by the wearer;

When the user wants to define certain data as an abnormal state or a data bottom line, the operation can be performed through the integrated control panel 107, and through the setting of the display 106, the user and the wearer can view the heart rate or other data in real time.

Working principle: When using the external defibrillator ECG monitoring device, first connect the ECG electrode 202 to the chest or abdomen of the wearer, then start the microprocessor 101, then the ECG electrode 202 will transmit the wearer's heart rate data to the conductor 201, and at the same time the conductor 201 will transmit the data to the ECG collector 102 inside the device body 100, then the ECG collector 102 will transmit the data to the microprocessor 101, and the microprocessor 101 will process the data through the ECG analyzer 103 and then Calculation is performed, and when the data shows abnormality, an alarm is issued through the alarm 108. When the data does not show abnormality, the microprocessor 101 transmits the data to the Bluetooth connector 104. At this time, the Bluetooth connector 104 searches for the automatic external defibrillator body 300 through the remote signal. When the signal of the automatic external defibrillator body 300 is not detected, the Bluetooth connector 104 issues an alarm through the alarm 108. When a signal is detected, the Bluetooth connector 104 transmits the data to the automatic external defibrillator body 300.

When the user wants to connect multiple ECG electrodes 202, they can be connected to the conductor 201 through the conductive wire 204, and the microprocessor 101 will transmit the data to the recorder 105 after processing the data, so as to record the working conditions of the device when it is worn by the wearer;

When the user wants to define certain data as an abnormal state or a data bottom line, the operation can be performed through the integrated control panel 107, and through the setting of the display 106, the user and the wearer can view the heart rate or other data in real time.

Thereby completing a series of tasks, the contents not described in detail in this specification belong to the prior art known to professional and technical personnel in this field.

Although the present invention has been described in detail with reference to the aforementioned embodiments, those skilled in the art may still modify the technical solutions described in the aforementioned embodiments, or make equivalent substitutions for some of the technical features therein. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of the present invention shall be included in the protection scope of the present invention.

Claims (7)

1. An external defibrillator ECG monitoring device, comprising a device body (100), a conductor (201) connected to the device body (100), and an automatic external defibrillator body (300), characterized in that: the device body (100) is connected to the conductor (201), and the conductor (201) is connected to the ECG electrode (202); A microprocessor (101) is provided inside the device body (100), and the microprocessor (101) is connected to an electrocardiogram collector (102) and an electrocardiogram analyzer (103), and a Bluetooth connector (104) is provided at the bottom of the microprocessor (101), and the Bluetooth connector (104) is connected to the bottom of the device body (100), and an alarm (108) is provided on the front side of the device body (100), and the alarm (108) is connected to the microprocessor (101). 2. The external defibrillator ECG monitoring device according to claim 1 is characterized in that a display (106) and an integrated control board (107) are provided on the front side of the device body (100), and the display (106) and the integrated control board (107) are connected to the microprocessor (101). 3. The external defibrillator ECG monitoring device according to claim 2, characterized in that a power supply (109) is provided inside the device body (100), and the power supply (109) can be connected to the microprocessor (101). 4. The external defibrillator ECG monitoring device according to claim 3 is characterized in that the microprocessor (101) is wired to the recorder (105), and the recorder (105) can input the stored data into the Bluetooth connector (104). 5. The external defibrillator ECG monitoring device according to claim 4, characterized in that a fixer (110) is provided outside the device body (100), and the fixer (110) is connected to the device body (100). 6. The external defibrillator ECG monitoring device according to claim 5 is characterized in that the microprocessor (101) inside the device body (100) transmits data to the automatic external defibrillator body (300) through a Bluetooth connector (104), and the Bluetooth connector (104) can be connected to the automatic external defibrillator body (300). 7. The external defibrillator ECG monitoring device according to claim 6 is characterized in that: a connecting line (203) is provided on the top of the device body (100), and the device body (100) is connected to the conductor (201) through the connecting line (203), and the conductor (201) is connected to the ECG electrode (202) through the conducting line (204), and the inner side of the ECG electrode (202) has a certain degree of stickiness.