KR20090040945A - Apparatus for measuring the pulse - Google Patents

Abstract

An apparatus for measuring a pulse is provided to measure a pulse by measuring an eddy current loss change of an AC magnetic field according to contraction and expansion of an artery. An apparatus for measuring a pulse includes an eddy current generating part(20), an eddy current sensing part(30), and a signal processing part(40). The eddy current generating part generates an AC magnetic field near an artery. The eddy current sensing part senses an eddy current loss change of the AC magnetic field according to contraction and expansion of the artery. The signal processing part outputs a pulse signal according to the eddy current loss change by processing a signal sensed by the eddy current sensing part. The eddy current generating part generates the AC magnetic field by an AC power source(50) having a frequency of about 300KHz. The eddy current sensing part senses a different value of an eddy current sensed near the eddy current generating part.

Description

Pulse measuring device {APPARATUS FOR MEASURING THE PULSE}

The present invention relates to a pulse measuring apparatus, and more particularly, a pulse measuring apparatus capable of measuring a pulse due to contraction and expansion by detecting a change in the amount of eddy current loss of an alternating magnetic field generated around an artery as the artery contracts and expands. It is about.

In general, the pulse is a change in the pressure in the artery according to the heartbeat, which is about 60 to 80 times per minute for normal adults, about 90 to 140 times per minute for infants, and about 70 to 80 times per minute for older people. This pulse rate is used to view the state of the whole body or to diagnose the circulatory system.

In order to measure such pulse, the pulse rate was countered by measuring the time separately with the thumb pointing at the radial artery (撓 骨 動脈) located on the thumb side of the wrist joint, but using electronic application technology and semiconductor chip. In recent years, due to the improvement in manufacturing technology, pulses are detected by using an electric method or piezoelectric elements, and as the interest in health becomes greater, they carry devices that can check their own health at all times.

However, as a general pulse measuring device, a piezoelectric element is used, which measures pressure change due to contraction and expansion of an artery. In order to measure a pulse, a measuring device must be pressed against the skin.

The present invention was created to solve the above problems, an object of the present invention is to measure the change in the amount of eddy current loss of the alternating magnetic field generated around the artery in accordance with the contraction and expansion of the artery to measure the pulse according to the contraction and expansion It is to provide a pulse measuring device to enable.

Pulse measuring apparatus according to the present invention for achieving the above object detects the eddy current generating unit for generating an alternating magnetic field around the artery, and the change in the amount of eddy current loss of the alternating magnetic field generated by the eddy current generating unit in accordance with the contraction and expansion of the artery An eddy current detection unit for processing, and a signal processing unit for processing the signal sensed by the eddy current detection unit to output a pulse signal according to the eddy current loss amount change.

In the present invention, the eddy current generating unit is characterized by generating an AC magnetic field by receiving an AC power source having a frequency of about 300KHz.

In the present invention, the eddy current detection unit is characterized in that it detects the difference value of the eddy current of the alternating magnetic field detected around the eddy current generating unit.

Pulse measuring device according to the present invention is a magnetic body having a plurality of peripheral projections protruded from the center projection and the periphery of the central projection is connected to each other and the center of the other side, and the center projection is wound around the AC power input AC power field A coil for generating a plurality of coils, a plurality of sensing coils for sensing an eddy current of an alternating magnetic field generated by the winding coils, and a variation in the amount of eddy current loss of the alternating magnetic field detected by the plurality of sensing coils And a signal processor for processing a signal output from the comparator and outputting the signal as a pulse signal.

In the present invention, the plurality of peripheral projections are characterized in that each projection at the same interval as the central projection.

In the present invention, the central projection and the plurality of peripheral projections are characterized in that the projection in the same direction.

In the present invention, the other side of the magnetic material is characterized in that the eddy current shield is formed to shield the eddy current present in the surroundings.

In the present invention, the plurality of sensing coils are serially connected so that the output becomes 0 when symmetrical conditions are applied to the comparator.

In the present invention, the magnetic material is characterized in that the ferrite core.

AC power in the present invention is characterized in that having a frequency of about 300KHz.

In the present invention, the magnetic material is characterized in that the "yama" shape.

As described above, the present invention has the effect of measuring the heart rate in the wrist by measuring the pulse rate according to the contraction and expansion by measuring the change in the eddy current loss of the alternating magnetic field generated around the artery as the artery contracts and expands. .

In addition, even if the skin is not compressed, the pulse can be measured by the change in the amount of eddy current loss of the alternating magnetic field, thereby improving the fit.

In addition, the pulse can be detected in the absence of pressure, there is an effect that can be measured stable without discomfort during exercise.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings, and the same parts as in the prior art use the same reference numerals and names. In addition, the present embodiment is not intended to limit the scope of the present invention, but is presented by way of example only and those skilled in the art will be capable of many modifications within the technical spirit of the present invention.

1 is a block diagram showing a pulse measuring apparatus according to the present invention.

As shown here, the eddy current generating unit 20 for generating an alternating magnetic field around the radial artery of the wrist 10 joint, and the eddy current generating unit 20 according to the contraction and expansion of the artery. An eddy current detection unit 30 for detecting a change in the eddy current loss amount of the generated AC magnetic field, and a signal processing unit 40 for processing the signal detected by the eddy current detection unit 30 to output a pulse signal according to the eddy current loss amount change. .

The pulse measuring device made in this way receives an AC power source of about 300 KHz from the eddy current generating unit 20 to generate an AC magnetic field, so that the eddy current of the AC magnetic field generated in the eddy current generating unit 20 is applied to the contraction and expansion of the artery. The loss of eddy current occurs due to the cross-sectional area of the artery and the conductor of blood, and the signal processor 40 detects a change in the amount of eddy current loss that is out of balance, and outputs a pulse signal that can be counted by signal processing. Make sure

In the present embodiment, the pulse is measured in the radial artery of the wrist joint, but the pulse rate can be measured by installing any part that can measure the pulse including the radial artery.

2 is a configuration specifically showing a pulse measuring apparatus according to the present invention.

As shown here, a ferrite core having a central protrusion 22 having one side connected to each other and a central portion protruding from the other side and a first to second peripheral protrusions 32 and 33 protruding from the periphery of the central protrusion 22. Of the magnetic body 80, the center projection 22 is wound on the feed coil 24 receives the AC power source 50 to generate an AC magnetic field, and the first to second peripheral projections (32) (33) AC magnetic field detected by the first to second sensing coils 34 and 35 and the first to second sensing coils 34 and 35 for sensing the eddy current of the AC magnetic field generated by the feed coil 24. The comparator 70 detects a change in the amount of eddy current loss, and the signal processor 40 processes a signal output from the comparator 70 and outputs a pulse signal.

At this time, the first to second peripheral protrusions 32 and 33 of the magnetic body 80 are respectively protruded at the same interval as the central protrusion 22, the central protrusion 22 and the first to second peripheral protrusions 32. Reference numeral 33 is a projection in the same direction to form a "mountain" shape.

In addition, an eddy current shield 60 is formed on the other side of the magnetic material 80 to shield eddy currents present in the surroundings so that the eddy current generated in the feed coil 24 is not caused by the alternating magnetic field present in the surroundings.

In addition, the first to second sensing coils 34 and 35 are connected by winding one wire, and the lead wire of the first sensing coil 34 and the lead wire of the second sensing coil 35 are connected to the comparator 70. It is applied to detect the difference between the eddy current of the alternating magnetic field detected by the first sense coil 34 and the second sense coil (35).

That is, the first to second sensing coils 34 and 35 are serially connected so that the output becomes 0 when symmetrical conditions are applied to the comparator 70.

Therefore, as shown in FIG. 3, when the AC power supply 50 is applied to the feed coil 24, the eddy current caused by the AC magnetic field is distributed in a right and left balance.

The pulse measuring device according to the present invention is configured to apply an AC power supply 50 having a frequency of about 300 KHz to the feeding coil 24 in a state in which the magnetic body 80 is close to the radial artery of the wrist 10. 24, when the alternating magnetic field is generated and applied to the radial artery, the eddy currents of the alternatingly distributed AC magnetic field are balanced as shown in FIGS. 4A and 4B. In case of contraction and expansion, loss of eddy current occurs and it is distributed unevenly.

When the non-uniform distribution of the loss amount of eddy current is detected through the eddy current detection unit 30 as described above, the frequency of 300 KHz as in the signal processing process shown in FIG. 5 when the radial artery 15 is repeatedly expanded and contracted. Each time it detects a signal whose amplitude changes. The detected signal is subjected to full-wave rectification as shown in (b) in the signal processor 40, and then only frequency components are extracted as shown in (c) and converted into square waves as shown in (d).

Therefore, the eddy current distributed in a balanced manner by the radial artery 15 detects the difference value of the eddy current lost due to the contraction and expansion of the radial artery 15, that is, the change amount through the comparator 70 to detect the difference in the signal processing unit ( By converting the pulse signal through 40), pulses varying according to the contracted and expanded states of the radial artery 15 can be counted to measure the pulse rate.

1 is a block diagram showing a pulse measuring apparatus according to the present invention.

2 is a configuration diagram specifically showing a pulse measuring apparatus according to the present invention.

3 is a view showing the eddy current of the alternating magnetic field generated in the pulse measuring apparatus according to the present invention.

4 (a) is a diagram showing the eddy current of the alternating magnetic field in the state in which the artery is contracted, (b) is a diagram showing the eddy current of the alternating magnetic field in the state in which the artery is expanded.

5 is a graph showing a signal processing procedure of the pulse measuring apparatus according to the present invention.

   -Explanation of symbols for the main parts of the drawings-

10: wrist 15: radial artery

20: eddy current generating unit 22: center projection

24: power supply coil 30: eddy current detection unit

32, 33: first to second periphery

34, 35: 1st to 2nd detection coil

40: signal processor 50: AC power

60: eddy current shield 70: comparison unit

80: magnetic material

Claims (11)

An eddy current generator for generating an alternating magnetic field around the artery, An eddy current detector for detecting a change in the amount of eddy current loss of the AC magnetic field generated in the eddy current generator according to the contraction and expansion of the artery; A signal processor for processing a signal sensed by the eddy current detector and outputting a pulse signal according to the eddy current loss amount Pulse measuring apparatus comprising a. The pulse measuring apparatus of claim 1, wherein the eddy current generator generates an AC magnetic field by receiving an AC power source having a frequency of about 300 KHz. The pulse measuring apparatus of claim 1, wherein the eddy current detecting unit detects a difference value of the eddy current detected around the eddy current generating unit. A magnetic body having one side connected to each other and a central protrusion having a central portion protruded from the other side and a plurality of peripheral protrusions protruding from the periphery of the central protrusion; A winding coil wound around the center projection to receive an AC power and generating an AC magnetic field; A plurality of sensing coils wound around the plurality of peripheral protrusions for sensing an eddy current of an AC magnetic field generated in the feed coil; A comparator for detecting a change in the amount of eddy current loss of the alternating magnetic field detected by the plurality of sensing coils; Signal processing unit for processing the signal output from the comparison unit to output a pulse signal Pulse measuring apparatus comprising a. The pulse measuring apparatus according to claim 4, wherein the plurality of peripheral protrusions are respectively protruded at the same interval as the center protrusion. The pulse measuring apparatus according to claim 4, wherein the center protrusion and the plurality of peripheral protrusions are protruded in the same direction. The pulse measuring apparatus according to claim 4, wherein an eddy current shield is formed on the other side of the magnetic material to shield eddy currents that exist around the magnetic body. The pulse measuring apparatus of claim 4, wherein the plurality of sensing coils are serially connected so that an output becomes 0 when symmetrical conditions are applied to the comparator. The pulse measuring apparatus according to claim 4, wherein the magnetic body is a ferrite core. 5. The pulse measuring apparatus according to claim 4, wherein said AC power source has a frequency of about 300 KHz. 5. The pulse measuring apparatus according to claim 4, wherein the magnetic body is in the shape of a "mountain".

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