KR100977480B1 - Pulse device - Google Patents

Abstract

The present invention relates to a pulsation device, comprising: a pulse device for displaying pulse waves of a wrist of a patient on a screen using a cuff, the first pressure sensing unit measuring at least one portion of the pulse waves of the wrist, the total pressure of the cuff A second pressure detector to measure, an input unit to input and filter the detected signals of the first and second pressure detectors, an A / D conversion unit to digitally convert the filtered pulse wave signal of the input unit, and the A / D conversion Comprising a calculation unit to obtain a pulse image by analyzing and calculating the pulse wave in accordance with the output of the negative portion, and a display unit for displaying the pulse image in accordance with the output of the calculation unit, the first pressure sensing unit is a plurality of pressure sensors to measure the pulse wave in contact with the wrist of the patient Characterized in that consists of.

By using the above pulsating device, it is possible to obtain an accurate patient's pulse image by pulsating the oscillometric method and the tonometric method.

Oscillometric, Tonometric, Pulse Wave, Pulse, Pressure

Description

Pulse measuring apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a pulsation apparatus, and more particularly, to an apparatus for extracting an accurate pulse image from a pulse wave by using a plurality of pressure sensors provided in the cuff portion and a pressure sensor for measuring the pressure of the entire cuff portion.

In general, auscultation methods and oscillometric methods are the most widely used methods for measuring heart contraction pressure and diastolic pressure.

In the stethoscope method, the cuff is wrapped around the upper arm and then pressurized, and the stethoscope is placed in front of the elbow.

If the pressure in the cuff is too small, the blood will easily fill the artery, and even with a pulse, the stethoscope will not hear anything.

However, if the pressure in the cape is high enough to block blood flow in the arteries during any interval of the heartbeat cycle, you will hear the stethoscope at the heart beat.

This sound is called a Korotkoff sound.

To measure blood pressure using the auscultation method, first apply pressure to the cuff at a pressure higher than the arterial contractile pressure.

The arteries of the arm are compressed, blocking blood flow, and no Korotkoff sounds.

When the pressure in the cuff decreases slightly below the heart contraction pressure of the artery, some blood flows through the blood vessel under the cuff.

Hearing the tap sound in sync with the heartbeat in the artery in front of the elbow and at the same time reading the pressure detected by the pressure sensor connected to the cuff, it is almost equal to the heart contraction pressure.

In addition, the oscillometric method discloses a technique for detecting waveforms in arterial vessels using electronic sensors and evaluating high pressure and low pressure using experimental parameters.

In addition, such an example is disclosed in Korea Patent Publication No. 2001-0084761 (September 06, 2001) and the like.

That is, as shown in FIG. 1, the document winds the A cuff 1 and the B cuff 2 around the upper arm of the test subject, and when the pressure is applied to the B cuff 2 until the artery is touched, Only the B cuff 2 touches the artery but does not compress the artery.

That is, since blood flows in the artery without obstruction, the waveform of the pulse of the artery detected by the sensor in the B cuff 2 is unchanged and uniform.

Then, if pressure is applied to the A cuff 1, when the pressure in the A cuff 1 is less than or equal to the lowest pressure of blood, the waveform detected by the sensor in the B cuff 2 is still unchanged.

However, when the pressure is continuously applied to the A cuff 1 so that the pressure in the A cuff 1 exceeds the lowest pressure of blood, the artery will be compressed.

At this time, the sensor in the B cuff 2 detects the waveform, the pressure at which the waveform changes is the cardiac dilatation pressure.

If pressure is continuously applied to the A cuff 1 so that the stress of the A cuff 1 on the blood vessel of the artery is continuously increased, the blood flowing through the A cuff 1 will be continuously reduced.

Although the blood flow rate is reduced, the sensor in the B cuff 2 can still detect the blood pulse and if pressure is continuously applied to the A cuff 1 so that blood flow in the artery is blocked, then the sensor in the B cuff 2 is A technique that can not detect blood flow in the arteries and can not detect any blood flow is a cardiac contraction pressure to measure the cardiac dilation pressure and systolic pressure sequentially.

However, the above-described Korean Unexamined Patent Publication No. 2001-0084761, etc., because the cuff is wrapped around the entire cuff (or wrist) and there is a pneumatic tube inside to detect the pressure to press the entire cuff, the accuracy is reduced, and the amount of blood flow changes There is a problem that it is difficult to define a pulse wave because the measuring method is a principle of detecting a volume pulsation rather than a pressure pulsation.

An object of the present invention is to solve the problems described above, and combines the oscillometric method and the toometric method, the amount of pressure applied to the entire cuff and the amount of pressure applied to the small area. It is to provide a pulsation device that obtains an accurate pulse image from the pulse wave.

According to the pulsation device according to the present invention, the effect of obtaining an accurate patient's pulse with a pulsation integrating the oscillometric method and the tonometric method is obtained.

In order to achieve the above object, a pulsation device according to the present invention is a pulsation device for displaying a pulse wave of a wrist of a patient on a screen using a cuff, the first pressure sensing unit for measuring at least one portion of the pulse wave of the wrist, the cuff A second pressure detector for measuring the total pressure of the input unit, an input unit for inputting and filtering the detected signals of the first and second pressure detectors, an A / D converter for digitally converting the filtered pulse wave signal of the input unit, and Comprising a calculation unit to obtain a pulse image by analyzing and calculating the pulse wave in accordance with the output of the A / D conversion unit, and a display unit for displaying the pulse image in accordance with the output of the calculation unit, wherein the first pressure sensing unit to measure the pulse wave in contact with the wrist of the patient Composed of a plurality of pressure sensors for the calculation unit, the total pressure detected by the second pressure sensing unit at the pressure value of the specific local portion detected by the first pressure sensing unit The is characterized in that for calculating the pressure variation in the specific small areas by subtracting.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention, through which the purpose and features of the present invention will be more clear.

2 is a view showing the pulse to be measured of the patient wrist according to the present invention, Figure 3 is a view showing the arm of the patient wearing a pulsation device according to the present invention, Figure 4 is a pulse according to the present invention It is a block diagram of the device.

As shown in Figure 2, the wrist of the patient according to an embodiment of the present invention has three points, the village, the tube, the chuck is extracted pulse wave.

The pulse wave is extracted by using the pressure sensor 130 provided in the cuff part 110 at the three points, and the extracted pulse wave is calculated by calculating the extracted pulse wave to diagnose abnormalities of the five intestines of the human body.

Dermatology of oriental medicine is an important diagnostic method in the field of oriental medicine because it is possible to know the physical condition of the patient through the pulse of the radial artery and the pressure of the finger.

Until now, the traditional pulse method is highly dependent on the sense of oriental medicine and there is no quantitative quantification.

In general, the pulsator recognizes the pulses generated in the radial artery of the right wrist of the human body and displays the waveforms of the 28 kinds of veins used in oriental medicine as graphs to objectively detect the loss of yin and yang inside the human body. How to diagnose.

Traditional pulsation method is to check the patient's condition by pressing the pressure in the village, tube, chuck area and observing the change of pulse wave to obtain a pulse.

The present invention relates to an apparatus for quantifying vein data by classifying vein images on the basis of the data on which the sensor is located and measured according to the classification principle of vein images based on Oriental Medicine.

The vein is composed of temporal features, spatial features, intensities, and veins definable through the combination of the three at the hill, duct, and chuck sites.

In the present invention, the pressure sensor 130 is vertically located in the B direction (horizontal) of FIG. 2 to distinguish the veins according to the temporal characteristics, and the pressure sensor is positioned in the A direction (vertical) of FIG. 2 according to the spatial characteristics.

In addition, in order to distinguish the strength of the force discreetly, the pressure value of the part compared to the pressure value applied to the entire area around the radial artery is determined so that the pneumatic tube is configured to pressurize around the radial artery.

Pulse pressure should be measured according to the total amount of pressure, partial blood pressure change should be widely distributed around the village, tube, chuck can be extracted vein.

And, six hatched pressure sensor 130 of Figure 4 is in close contact with the village, pipe, chuck.

As shown in FIG. 3, a diagram illustrating an arm of a patient wearing a pulsation device according to an exemplary embodiment of the present invention prevents the movement of the patient and supports the arm and the cuff of the arm to support the arm for accurate pulse measurement. It consists of 110.

The cuff portion 110 is formed of a rubber tube, provided with a first pressure sensing unit 120, the first pressure sensing unit 120 measures the pressure of the individual area is pressed when the rubber tube is contracted It is composed of a plurality of pressure sensors 130.

In addition, the cuff part 110 may be integrated into the control device (150, 160, 170, 180) or attached to the outside.

As shown in Figure 4, the pulsation device according to an embodiment of the present invention is the first pressure detection unit 120, the first and second pressure detection for simultaneously measuring the pressure applied to the wrist of the patient divided into partial areas An input unit 150 for inputting and filtering the detected signals of the units 120 and 140, an A / D converter 160 for converting the filtered pulse wave signal of the input unit 150 into digital, and the A / D converter 160 And a display unit 180 for displaying a pulse image according to the output of the calculation unit 170.

The first pressure detection unit 120 is composed of a total of 18 pressure sensors 130, the second pressure detection unit 140 is formed of a pressure sensor to detect the air pressure inside the rubber tube of the cuff portion 110. .

In addition, the cuff portion 110 is provided with an air pump (not shown) for pressure control or the like to adjust the overall pressing force.

The present invention is an oscillometric method and a tonometric method is a pulsator is integrated, the oscillometric method is to cover the entire wrist by a cupra and pressurizes the entire wrist area because there is a pneumatic tube inside, the detection method is a whole area Accuracy is inferior because pulse wave is detected, and it is difficult to define pulse wave because the method of measuring the amount of blood flow changes is the principle of detecting volume pulse, not pressure pulse.

The tonometric method is the most suitable method to detect the pulse wave of the pressure pulsation with a minimum pressure on a small area, and it is difficult to detect the pulse wave in the radial artery by occupying the small area, and usually uses an array-type tonometric method.

Since the toometric method presses on a small area, it is difficult to calculate the exact amount of pressurization, and thus the amount of pulse wave change compared to the pressing force cannot be known.

Therefore, when combined with the oscillometric method, the cuff can be measured while pressing the cuff, thereby quantifying the pulse wave variation according to the individual's blood pressure.

In other words, the peak pressure and the lowest blood pressure are determined according to the pressing force of the cuff, and the largest pulse wave can be measured between the highest blood pressure point and the lowest blood pressure point, so that the individual pulse wave waveform can be defined in a specific form.

In other words, the tonometric method detects the amount of change at each minute portion, and the oscillometric method can know the total amount of pressurization and the total amount of change.

The total amount of pressurization = the pressure of the cuff + the sum of the changes in the micro area-(Equation 1)

Change amount (in pressure value mmHg) at a specific local area = Converted voltage value (unit V) sensed at a specific local area to pressure value (mmHg)-Total pressure (mmHg) --- (Equation 2)

In the above equation, the amount of change at a specific local site can be obtained by the above equation, so that the pulse wave of the radial artery can be detected. The above equations (1, 2) are performed by the operation of the control unit 170, and the pulse wave is applied to each local site. Detecting is to detect a wound.

In order to detect a vein, it is necessary to know the amount of change in each part with pressure.

The present invention can know the total amount of pressure and the amount of change in each site, and systematic pulse wave classification is possible according to the individual blood pressure value.

As mentioned above, although the invention made by the present inventor was demonstrated concretely according to the said Example, this invention is not limited to the said Example and can be variously changed in the range which does not deviate from the summary.

1 is a view showing a pair of cuffs wound around the upper arm of the test subject according to the prior art,

2 is a view showing the pulse to be measured of the patient wrist according to the present invention,

3 is a view showing the arm of the patient wearing the pulsation device according to the present invention,

4 is a block diagram of a pulsation device according to the present invention;

* Description of the symbols for the main parts of the drawings *

110: cuff part

120: first pressure detection unit

130: pressure sensor

Claims (4)

In the pulsation device for displaying the pulse wave of the wrist of the patient on the screen using a cuff, A first pressure detecting unit measuring at least one portion of the pulse wave of the wrist; A second pressure sensing unit measuring the total pressure of the cuff; An input unit configured to input and filter the detected signals of the first and second pressure detectors; An A / D conversion unit for converting the filtered pulse wave signal into a digital unit; An arithmetic unit that obtains a pulse image by analyzing and calculating a pulse wave according to the output of the A / D converter; It is composed of a display unit for displaying a pulse image in accordance with the output of the operation unit, The first pressure sensing unit is composed of a plurality of pressure sensors for measuring the pulse wave in contact with the wrist of the patient, the calculation unit is detected by the second pressure sensing unit at the pressure value of the specific local portion detected by the first pressure sensing unit Pulsation device, characterized in that to calculate the amount of pressure change in a particular local area by subtracting the total amount of pressure. delete The method of claim 1, The pulsation device is characterized in that it comprises a cradle for supporting the arm of the patient to prevent the movement of the arm of the patient, to measure the accurate pulse. The method of claim 1, The first pressure sensing unit has six portions in contact with the wrist in a horizontal direction. Pulse device characterized in that three pressure sensors are formed in the longitudinal direction.

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