KR102581095B1 - Wireless ECG that does not cause errors as a result of abnormal electrode position - Google Patents

Abstract

The present invention recognizes the position between each electrode and converts each electrode into a receiver appropriate for the position where it is attached, so that even if a doctor or electrocardiographer mistakenly attaches electrodes to the wrong position, the position of each electrode is recognized regardless of the position of the electrodes. It relates to a wireless electrocardiogram measurement device that can measure without electrode discrimination based on electrode position recognition function that transmits and interprets signals.
For this purpose, the wireless ECG measurement device, which can measure without electrode distinction based on electrode position recognition function, has 6 chest electrodes (v1~v6) and 4 left and right/upper and lower limb electrodes (aVR, aVL, aVF(right), aVF(left)). ), wherein each electrode is equipped with a transmitter and is attached to the skin to detect an electrical signal. At least two electrodes are disposed at positions adjacent to the electrodes, and each position of the electrodes is After identifying and interpreting the electrodes, it includes a reference that provides information so that the electrodes can recognize and interpret the electrode positions on their own, and an electrocardiogram measurement unit that measures the electrocardiogram based on the signals of each electrode whose position is determined by the reference. .

Description

Wireless ECG measurement device that can measure electrodes without distinction based on electrode position recognition function {Wireless ECG that does not cause errors as a result of abnormal electrode position}

The present invention relates to a wireless electrocardiogram measuring device capable of measuring without electrode distinction based on electrode position recognition function.

An electrocardiogram (ECG) is a measurement of electrical potentials related to heartbeat on the surface of the body, and is often used in clinical practice because it can be measured through a non-invasive test without causing pain or side effects to the subject.

In addition, the electrocardiogram is used as a basic method to check for heart abnormalities and diagnose heart diseases such as angina pectoris, myocardial infarction, and arrhythmia.

Additionally, in order to diagnose the various cardiac diseases described above, a 12-channel electrocardiogram is measured. For example, conventionally, a 12-channel electrocardiogram is measured using information obtained through 10 electrodes.

In order to measure the electrocardiogram, a plurality of electrodes attached to the body are connected to each other by wires. Therefore, there is a problem that the activity of the test subject is limited while measuring heart rate due to complicated wires.

In addition, in order to obtain a precise electrocardiogram waveform, a total of 10 electrodes, V1 to V6, left and right/upper and lower limbs, must be attached to the correct location on the body. The upper and lower limbs on both sides of the body are mainly classified by color, but due to the operator's mistake, the left and right electrodes are often mixed. /There are cases where the upper and lower limbs are confused and attached incorrectly.

The above ECG electrodes V1 to V6 are chest electrodes, and electrodes designated from the right chest to the left chest must be attached to the chest in order without error to obtain accurate ECG results. However, this also causes many electrode position errors and is often the wrong electrode. Incorrect ECG results are produced due to location (V1~V6 location errors, especially the location of the left and right/upper and lower extremity electrodes are changed, resulting in frequent erroneous EKG tests).

Republic of Korea Patent Publication No. 10-1651537 (Title of invention: Electrocardiogram measurement device and method using wireless communication, announced on August 26, 2016) Republic of Korea Patent Publication No. 10-2020-0075780 (Title of invention: Wireless electrocardiogram measuring device, published on June 26, 2020)

The present invention was created in consideration of the above points. It recognizes the position between each electrode and converts each electrode into a receiver appropriate for the position where it is attached, so that even if a doctor or electrocardiographer mistakenly attaches the electrode to the wrong position, the electrode is not detected. The purpose is to provide a wireless electrocardiogram measurement device that can measure without electrode discrimination based on an electrode position recognition function that recognizes the positions of each electrode and transmits and interprets signals regardless of the position of the electrodes.

According to a preferred embodiment for achieving the purpose of the present invention described above, the wireless electrocardiogram measuring device capable of measuring without electrode distinction based on the electrode position recognition function according to the present invention includes six chest electrodes (v1 to v6) and four It consists of left and right/upper and lower limb electrodes (aVR, aVL, aVF (right), aVF (left)), and each electrode is equipped with a transmitter and is attached to the skin to detect an electrical signal. The electrode part of the wireless Bluetooth, the electrode part At least two or more references are disposed in adjacent positions, and after identifying and interpreting each position of the electrodes, the electrodes provide information to recognize and interpret the electrode positions on their own, and the positions are determined by the references. It may include an electrocardiogram measuring unit that measures the electrocardiogram based on signals from each of the electrodes.

The reference recognizes the position between each electrode and can be converted from the position where each electrode attaches itself to a receiver suitable for that position.

The reference includes a first reference and a second reference, the distance between the first reference and the electrode or the distance between the second reference and the electrode, and the first reference, the electrode, and the second reference are The position of the electrode can be set by converting the angle formed into data.

Through the signals of the first reference and the second reference, no matter what position the six chest electrodes are attached to, they are recognized as V1 to V6 in that order, and no matter what position the four left and right/upper and lower limb electrodes are attached to, the electrodes are automatically positioned at the electrodes. After analyzing and interpreting to the appropriate place, the signal can be transmitted.

In addition, the wireless electrocardiogram measuring device that can measure without electrode distinction based on the electrode position recognition function according to the present invention consists of six chest electrodes and four left/right/upper/lower limb electrodes, and each electrode is equipped with a transmitter to transmit an electrical signal. In order to detect, the electrode part of the wireless Bluetooth attached to the skin is installed on at least two of the six chest electrodes and the four left and right/upper and lower limb electrodes. After identifying and analyzing the positions of each of the electrodes, the electrodes are self-destructive. It may include a reference sensor that provides information to recognize and interpret the electrode position, and an electrocardiogram measurement unit that measures the electrocardiogram based on the signal of each electrode whose position is determined by the reference sensor.

The reference sensor is made of a button type, and the position between each electrode is recognized by the on operation of the reference sensor, so that each electrode can be converted from a self-attached position to a receiver suitable for that position.

The reference sensor includes a first reference sensor and a second reference sensor, the distance formed by the first reference sensor and the electrode or the distance formed by the second reference sensor and the electrode, and the first reference sensor and the electrode And the position of the electrode can be set by converting the angle formed by the second reference sensor into data.

No matter where the six chest electrodes are attached, they are recognized as V1 to V6 in order through the signals from the first reference sensor and the second reference sensor, and no matter where the four electrodes of the left and right/upper and lower limbs are attached, the electrodes operate on their own. After analyzing the electrode location and interpreting it to an appropriate location, the signal can be transmitted.

According to the wireless electrocardiogram measuring device that can measure without distinguishing between electrodes based on the electrode position recognition function according to the present invention, it is possible to recognize each other's positions between electrodes and transmit and interpret signals, resulting in incorrect location due to a doctor or electrocardiographer's error. When attaching electrodes to the ECG, it is possible to prevent ECG results from being output on an incorrect result sheet.

In addition, the device can be simplified by using electrocardiogram electrodes without connecting wires, and each electrode can be converted into an appropriate receiver at its own attachment location through a reference, providing more convenience to doctors and electrocardiographers performing electrocardiogram tests.

Figure 1 is a diagram showing a wireless electrocardiogram measuring device according to an embodiment of the present invention.
Figure 2 is a diagram illustrating a state in which electrode positions of a wireless electrocardiogram measuring device are determined according to an embodiment of the present invention.
Figure 3 is a diagram showing a wireless electrocardiogram measuring device according to another embodiment of the present invention.
FIG. 4 is a diagram illustrating a state in which the electrode positions of the wireless electrocardiogram measuring device of FIG. 3 are determined.

Hereinafter, with reference to the attached drawings, an embodiment of a wireless electrocardiogram measuring device capable of measuring without electrode distinction based on the electrode position recognition function according to the present invention will be described. At this time, the present invention is not limited or limited by the examples. Additionally, when describing the present invention, detailed descriptions of well-known functions or configurations may be omitted to make the gist of the present invention clear.

Figure 1 is a diagram showing a wireless electrocardiogram measuring device according to an embodiment of the present invention. Figure 2 is a diagram illustrating a state in which electrode positions of a wireless electrocardiogram measuring device are determined according to an embodiment of the present invention.

Referring to Figures 1 and 2, the wireless electrocardiogram measuring device (1) capable of measuring without electrode distinction based on the electrode position recognition function according to the present invention includes an electrode unit (10), a reference (20), and an electrocardiogram measuring unit ( 30), and the electrocardiogram signal transmitted from the electrode unit 10 through wireless Bluetooth can be measured through the electrocardiogram measuring unit 30. The position of each electrode can be determined through the reference 20.

In this embodiment, the electrode unit 10 of the wireless electrocardiogram measuring device 1 includes six chest electrodes (V1 to V6) and four left and right/upper and lower limb electrodes (aVR, aVL, aVF (right), aVF (left)). ), each electrode is equipped with a transmitter 11 and is attached to the skin to detect an electrical signal. Since each electrode transmits an electrocardiogram signal using wireless Bluetooth, there is no separate connection line. .

Each of the electrodes includes an electrode rechargeable battery, a battery rechargeable electrode, and a Bluetooth receiver, and each charged electrode is attached to the skin of the subject to measure the electrocardiogram.

In addition, at least two or more references 20 are disposed at positions adjacent to the electrode unit 10, and after identifying and analyzing each position of the electrodes, information is provided so that the electrodes can recognize and interpret the electrode positions on their own. By providing, the reference 20 is installed at the top and bottom of the bed where the examinee is located, so that the position of each electrode can be determined.

In addition, the electrocardiogram measuring unit 30 measures the electrocardiogram based on the signals of each electrode whose position is determined by the reference 20, and the electrocardiogram measuring unit 30 is located adjacent to the bed where the subject is located. You can measure the electrocardiogram by placing the .

In other words, when the wireless electrocardiogram measuring device (1) attaches six chest electrodes and four left/right/upper/lower limb electrodes to the body of the examinee regardless of the designated positions, the wireless electrocardiogram measurement device (1) recognizes the position between each electrode by the reference (20) and The electrodes can be converted from a self-attached location to a receiver suitable for that location.

The wireless electrocardiogram measuring device (1) recognizes the position between each electrode as the reference (20) and can be changed into an appropriate receiver at the position where each electrode is attached. RSSI (Received Signal Strength Indication, Receive Signal Strength Indicator) ) is applied to each electrode to interpret the signal by recognizing the relative positions between the electrodes, and can receive biological electrocardiogram signals with electrodes suitable for their own positions.

In this embodiment, the reference 20 includes a first reference 21 and a second reference 22, and the distance formed between the first reference 21 and the electrode or the second reference 22 and The position of the electrode can be set by converting the distance between the electrodes and the angle between the first reference 21, the electrode, and the second reference 22 into data.

The first reference 21 is installed on a bed adjacent to the head of the examinee, and the second reference 22 is installed on a bed adjacent to the feet of the examinee, so that the position of each electrode can be determined.

Therefore, no matter what position the six chest electrodes are attached to through the signals of the first reference 21 and the second reference 22, they are recognized as V1 to V6 in order, and the four electrodes on the left and right/upper and lower limbs are positioned at any position. Even if it is attached, the electrodes can analyze the electrode position on their own, interpret it in an appropriate location, and then transmit a signal.

For example, when determining the location of the electrodes of the wireless ECG measuring device 1, the first reference 21 and the right upper limb electrode (aVR) are used to determine the electrode (aVR) attached to the right upper limb (right arm) of the subject. ), measure the distance (r1) between the second reference (22) and the upper right limb electrode (aVR), and measure the distance (r2) between the second reference (22) and the upper right limb electrode (aVR), and center the first reference (21) around the upper right limb electrode (aVR). By measuring the angle θ1 formed between and the second reference 22, the position of the right upper limb electrode can be determined.

In addition, in order to determine the sixth electrode (V6) of the chest electrodes of the subject, the distance (r1) between the first reference (21) and the chest electrode (V6) was measured, and the distance (r1) between the second reference (22) and the chest electrode ( The position of the chest electrode (V6) is determined by measuring the distance (r2) between the chest electrodes (V6) and measuring the angle (θ2) formed by the first reference (21) and the second reference (22) with the chest electrode (V6) as the center. can be figured out.

In other words, since the wireless electrocardiogram measuring device 1 includes a function to recognize and interpret the mutual positions between each electrode, even if six chest electrodes are attached regardless of order, it recognizes the positions of the chest electrodes in order and /Even if the four upper and lower limb electrodes are attached in any order, errors in ECG results can be prevented by automatically analyzing the electrode positions, interpreting them as appropriate positions, and then transmitting signals.

Figure 3 is a diagram showing a wireless electrocardiogram measuring device according to another embodiment of the present invention. FIG. 4 is a diagram illustrating a state in which the electrode positions of the wireless electrocardiogram measuring device of FIG. 3 are determined.

3 and 4, the wireless electrocardiogram measurement device 1 according to the present invention includes an electrode unit 10, a reference sensor 40, and an electrocardiogram measurement unit 30, and the electrode unit 10 The ECG signal transmitted through wireless Bluetooth can be measured through the ECG measurement unit 30. The position of each electrode can be determined through the reference sensor 40.

In this embodiment, the electrode unit 10 of the wireless electrocardiogram measuring device 1 includes six chest electrodes (v1 to v6) and four left and right/upper and lower limb electrodes (aVR, aVL, aVF (right), aVF (left)). ), each electrode is equipped with a transmitter 11 and is attached to the skin to detect an electrical signal. Since each electrode transmits an electrocardiogram signal using wireless Bluetooth, there is no separate connection line. .

In addition, the reference sensor 40 is installed on at least two of the six chest electrodes and the four left and right/upper and lower limb electrodes, and after identifying and analyzing the positions of each electrode, the electrodes independently determine the electrode positions. By providing information for recognition and interpretation, the reference sensor 40 is installed on two of the four left and right/upper and lower electrodes to determine the location of each electrode.

In addition, the electrocardiogram measuring unit 30 measures the electrocardiogram based on the signals of each electrode whose position is determined by the reference sensor 40, and the electrocardiogram measuring unit 30 is installed adjacent to the bed where the subject is located. ) can be placed to measure the electrocardiogram.

In other words, when the wireless electrocardiogram measuring device (1) attaches six chest electrodes and four left/right/upper/lower limb electrodes to the body of the subject regardless of the designated positions, the position between each electrode is recognized by the reference sensor (40). Each electrode can be converted from its self-attached location into a receiver appropriate for that location.

In this embodiment, the reference sensor 40 is in the form of a button, and the position between each electrode is recognized by the on operation of the reference sensor 40, and each electrode is converted from a self-attached position to a receiver suitable for that position. It can be.

The reference sensor 40 includes a first reference sensor 41 and a second reference sensor 42, and the distance between the first reference sensor 41 and the electrode or the second reference sensor 42 and The position of the electrode can be set by converting the distance between the electrodes and the angle between the first reference sensor 41, the electrode, and the second reference sensor 42 into data.

The first reference sensor 41 and the second reference sensor 42 are installed and used on two of the four left and right/upper and lower electrodes, or two of the four left and right/upper and lower electrodes on which the reference sensor 40 is all installed. By turning on the reference sensor 40 installed on the two electrodes, the first reference sensor 41 and the second reference sensor 42 can be identified and used.

Therefore, no matter where the six chest electrodes are attached through the signals of the first reference sensor 41 and the second reference sensor 42, they are recognized as V1 to V6 in order, and the four electrodes of the left and right/upper and lower limbs are positioned in any position. Even if it is attached to a location, the electrodes can analyze the electrode location on their own, translate it to an appropriate location, and then transmit a signal.

For example, when determining the location of the electrodes of the wireless electrocardiogram measuring device 1, the distance between the first reference sensor 41 and the chest electrode (V1) is used to determine the first electrode (V1) of the chest electrodes of the subject ( r1) is measured, the distance (r2) between the second reference sensor 42 and the chest electrode (V1) is measured, and the first reference sensor 41 and the second reference are centered on the chest electrode (V1). By measuring the angle θ1 formed by the sensor 42, the position of the chest electrode V1 can be determined.

In addition, in order to determine the fifth electrode (V5) of the chest electrodes of the subject, the distance (r1) between the first reference sensor 41 and the chest electrode (V5) is measured, and the distance (r1) between the second reference sensor 42 and the chest electrode is measured. The chest electrode ( You can determine the location of V5).

Therefore, since the wireless ECG measuring device 1 recognizes each other's positions between electrodes and is capable of transmitting and interpreting signals, if the electrodes are attached to the wrong location due to a doctor or ECG technician's mistake, the ECG results are output as incorrect results. This can be prevented in advance.

In addition, the device is simplified by using electrocardiogram electrodes without connecting wires, and each electrode is converted into an appropriate receiver at its self-attached position through the reference 20, providing more convenience to doctors and electrocardiographers performing electrocardiogram tests. .

Although the present invention has been shown and described in connection with preferred embodiments for illustrating the principles of the invention, the invention is not limited to the construction and operation as shown and described. Rather, those skilled in the art will understand that numerous changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims.

1: Wireless electrocardiogram measuring device 10: Electrode unit
11: Transmitter 20: Reference
21: first reference 22: second reference
30: ECG measuring unit 40: Reference sensor
41: first reference sensor 42: second reference sensor
V1~V2: Chest electrodes
aVR, aVL, aVF(right), aVF(left): Left and right/upper and lower limb electrodes
r1, r2: distance
θ1, θ2: Angle

Claims (8)

It consists of 6 chest electrodes (v1~v6) and 4 left/right/upper/lower limb electrodes (aVR, aVL, aVF(right), aVF(left)), and each electrode is equipped with a transmitter to detect electrical signals through the skin. Electrode portion of wireless Bluetooth attached to;
At least two references are disposed at positions adjacent to the electrode unit, identify and interpret each position of the electrodes, and then provide information so that the electrodes can recognize and interpret the electrode positions on their own; and
an electrocardiogram measuring unit that measures an electrocardiogram based on signals from each electrode whose position is determined by the reference; Including,
The reference includes a first reference and a second reference, the distance between the first reference and the electrode or the distance between the second reference and the electrode, and the first reference, the electrode, and the second reference are The position of the electrode is set by converting the angle formed into data,
The first reference is installed on a bed adjacent to the head of the examinee, and the second reference is installed on a bed adjacent to the feet of the examinee to determine the position of each electrode. An electrode based on an electrode position recognition function. A wireless electrocardiogram measuring device that can measure without distinction. According to claim 1,
The reference recognizes the position between each electrode and converts the position from where each electrode is attached to a receiver suitable for that position. A wireless electrocardiogram measuring device that can measure without electrode distinction based on an electrode position recognition function. delete According to claim 1,
Through the signals of the first reference and the second reference, no matter what position the six chest electrodes are attached to, they are recognized as V1 to V6 in that order, and no matter what position the four left and right/upper and lower limb electrodes are attached to, the electrodes are automatically positioned at the electrodes. A wireless electrocardiogram measurement device that can measure without electrode distinction based on an electrode position recognition function that analyzes and interprets to an appropriate location and then transmits the signal. A wireless Bluetooth electrode unit consisting of six chest electrodes and four left/right/upper/lower body electrodes, each of which is equipped with a transmitter and is attached to the skin to detect electrical signals;
A reference that is installed on at least two of the six chest electrodes and the four left and right/upper and lower limb electrodes, identifies and interprets the positions of each of the electrodes, and then provides information so that the electrodes can recognize and interpret the electrode positions on their own. sensor; and
an electrocardiogram measuring unit that measures an electrocardiogram based on signals from each electrode whose position is determined by the reference sensor; Including,
The reference sensor includes a first reference sensor and a second reference sensor, the distance formed by the first reference sensor and the electrode or the distance formed by the second reference sensor and the electrode, and the first reference sensor and the electrode And setting the position of the electrode by converting the angle formed by the second reference sensor into data,
The first reference sensor and the second reference sensor are installed and used on two of the four left and right/upper and lower electrodes, or the reference sensor is installed on two of the four left and right/upper and lower electrodes on which the reference sensors are all installed. A wireless electrocardiogram measuring device capable of measuring without distinguishing between electrodes based on an electrode position recognition function, characterized in that it is turned on and used specifically as the first reference sensor and the second reference sensor. According to claim 5,
The reference sensor is made of a button type, and is based on an electrode position recognition function, characterized in that the position between each electrode is recognized by the on operation of the reference sensor, and each electrode is converted from a self-attached position to a receiver suitable for that position. A wireless electrocardiogram measuring device that can measure without distinguishing between electrodes. delete According to claim 5,
No matter where the six chest electrodes are attached, they are recognized as V1 to V6 in order through the signals from the first reference sensor and the second reference sensor, and no matter where the four electrodes of the left and right/upper and lower limbs are attached, the electrodes operate on their own. A wireless electrocardiogram measurement device that can measure without electrode discrimination based on an electrode position recognition function that analyzes the electrode position, interprets it to an appropriate location, and then transmits a signal.

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