KR100919869B1 - Digital hemadynamometer of wristwatch type - Google Patents

Abstract

By raising or lowering the piezoelectric sensor that protrudes from the armband (compression band) to contact the radial artery of the wrist, it prevents numbness and can accurately detect blood pressure, and instead of inflating the entire wrist like a conventional blood pressure monitor, A wrist-type digital blood pressure monitor is provided that can reduce the noise caused by shaking the signal line of the piezoelectric sensor by swelling only the artery and pushing the radial artery. Wrist type digital sphygmomanometer, Blood pressure measuring unit for measuring the blood pressure by raising the position of the piezoelectric sensor in contact with the radial artery of the wrist when measuring the blood pressure of the human body; And a digital sphygmomanometer body for storing and displaying information on the blood pressure measured by the blood pressure measuring unit, wherein the blood pressure measuring unit is connected to the digital sphygmomanometer body and the wrist presses the wrist; An airbag installed on the armband and expanding in response to air injected through the air hose; And a piezoelectric sensor disposed above the airbag, rising upward in response to the inflation of the airbag, and measuring blood pressure in contact with the radial artery of the wrist.

Description

Wrist type digital sphygmomanometer {Digital hemadynamometer of wristwatch type}

The present invention relates to a blood pressure monitor, and more particularly, to a wrist-type digital blood pressure monitor for measuring the blood pressure of the human body.

Blood pressure is the pressure of the blood that spreads to the arteries as the heart relaxes, and the blood circulates through our bodies, providing nutrients and oxygen to the cells.

A hemadynamometer is a device for measuring blood pressure of a human body. There are two methods of measuring blood pressure, a direct method and an indirect method (compression method). The direct method is for animal experiments, and the measurement is made by directly inserting a thin tube called cathele into the carotid artery and connecting it to a pressure gauge. The indirect method is for the human body, usually referring to this. There are Rivaroche type blood pressure monitors using mercury barometer and Tycose type blood pressure monitors using aneroid barometer.

When you take your blood pressure, you record two values: 120/80 mmHg, for example, 120 is the systolic blood pressure that occurs when your heart contracts, and 80 is the diastolic blood pressure that occurs when your heart relaxes. For example, hypertension refers to a case in which the pressure of the heart provided to the blood vessels is high, and when an adult 18 years of age or older has a blood pressure of 140 mmHg / 90 mmHg or more measured twice or more at rest.

On the other hand, the wrist-type pulse wave detection watch is a device for measuring the pulsation or pulse wave of the radial artery, and the sensor for measuring the pulsation or pulse wave includes a semiconductor method, a press method, an optical method and a piezoelectric method.

Optical blood pressure detection sensor has the advantage of measuring light with a light emitting part and a receiving part and stably measuring blood pressure, but on the other hand, due to its large volume, it is difficult to miniaturize, high power consumption, and natural light There is a disadvantage that the measurement is difficult to measure in the place, that is, the outside. In addition, the semiconductor type blood pressure detection sensor has a disadvantage in that the power consumption is increased by measuring the change in resistance given the pressure. In addition, the press-type blood pressure detection sensor is also called a pneumatic blood pressure detection sensor, there is a disadvantage that the volume is large. In addition, the piezoelectric blood pressure detection sensor operates on the principle similar to that of the press type blood pressure detection sensor, and the piezoelectric blood pressure detection sensor does not consume power of the sensor itself, can be miniaturized, and can be used anywhere. have.

The blood pressure monitor according to the related art is a tool for health that is essential for hypertension patients or atherosclerosis patients, and is used to check a patient's health by measuring blood pressure of a patient at regular intervals. However, since the use of such a blood pressure monitor is difficult, patients have to visit a hospital at regular intervals and check their blood pressure from a nurse.

On the other hand, as a related prior art, Korean Patent Application No. 2003-700502 discloses a wrist-type digital blood pressure monitor named "apparatus for monitoring blood pressure". This wrist-type digital blood pressure monitor will be described with reference to FIGS. 1 and 2.

1 is a perspective view of a wrist-type digital blood pressure monitor according to the prior art, Figure 2 is a block diagram of a pressure sensor.

Referring to FIG. 1, the wrist-type digital blood pressure monitor according to the related art may include a pressure sensor 10, a blood pressure monitor body 20, and a band 30 and 40.

The pressure sensor 10 protrudes from the armbands 30 and 40 and contacts the radial artery of the wrist to measure blood pressure, and the blood pressure measured by the pressure sensor 10 is controlled by the microcomputer in the blood pressure monitor body 20. Is stored in the memory or displayed via the display.

Referring to FIG. 2, a pressure sensor 10 according to the prior art has a transducer 11 which generates a voltage output in response to a pressure change acting on a diaphragm 12. At this time, the plunger 13 is attached near the diaphragm 12 of the transducer 11.

The plunger 13 is a specially designed hemispherical component made of metal. The plunger 13 is placed on the diaphragm 12 of the transducer 11 to substantially cover the bottom of the transducer 11. The plunger 13 is pushed into the wrist to partially occlude the radial artery. The plunger 13 captures the transmission of the beating of the radial artery even though the wearer's hand is in various positions.

Between the diaphragm 12 and the plunger 13 is a layer of gel 14 that filters out and removes interference and abrupt changes due to unnatural movement. The gel 14 also buffers the noise ratio. The depth of the plunger 13 is designed to occlude less than half the diameter of the radial artery when the wrist is easily wound on most normal wrists.

However, according to the related art, as shown in FIG. 1, since the pressure sensor 10 is always protruding, the median nerve of the carpal tunnel is always compressed and worn within several minutes. Your fingers can numb. As a result, the hands or fingers can swell and cause additional congestion. In other words, the sensor is always attached to the arteries and the pressure is applied at the same time, sometimes blood can not pass through, jeopardy phenomenon may occur. Accordingly, there is a problem that not only greatly affect the measurement signal but also may be harmful to the wearer.

Technical problem to be solved by the present invention to solve the above problems, by lifting or lowering the piezoelectric sensor protruding from the armband in contact with the radial artery of the wrist, to prevent numbness phenomenon, wrist that can accurately detect blood pressure It is to provide a type digital sphygmomanometer.

Another technical problem to be solved by the present invention for solving the above-mentioned problems is not to swell the entire wrist like the conventional sphygmomanometer, but only to inflate the radial artery by pressing the radial artery, according to the signal line shaking of the piezoelectric sensor It is to provide a wrist-type digital blood pressure monitor that can reduce noise and motion artifacts.

As a means for achieving the above technical problem, the wrist-type digital sphygmomanometer according to the present invention, as described in claim 3, measuring the blood pressure, the wrist 210 connected to the sphygmomanometer body 100 and compresses the wrist And an airbag 220 installed on the armband 210 and inflated by the air injected through the air hose 222, and disposed above the airbag 220 and inflating and contracting the airbag 220. Piezoelectric sensor 230 for measuring the blood pressure of the radial artery by rising or lowering, band lower plate 212 for supporting the airbag 220, and disposed above the piezoelectric sensor 230 and the piezoelectric sensor 230 The elastic member 240 and the elastic member 240 is expanded in accordance with the rise of the) and the band lower plate 212 to form a housing and measure the blood pressure so that the piezoelectric sensor 230 and the elastic member 240 rise only to the radial artery part. Part is cut open Blood pressure measuring unit 200 having a band top plate 211 having a shape; And a memory 150 for storing blood pressure information measured by the blood pressure measuring unit 200, a display unit 140 for displaying the measured information, and air to the airbag 220 through the air hose 222. It includes a blood pressure monitor body 100 having a micro pump for injecting, the micro pump, providing a rotational power and the motor 370 is formed with an eccentric rotation shaft, the motor 370 is coupled and discharge the compressed air An upper plate 380 having a discharge port formed therein, and an elevating and lowering thereof are installed in the upper plate 380 by an eccentric rotation shaft 371 of the motor 370. A rubber pump 390 having an exhaust valve 391 for discharging the compressed air through the air hose 222 is coupled with the upper plate 380 to be kept airtight and is input by the rubber pump 390. Lower part with inlet Intake valve 310 is installed in the middle of the rate 320, the lower plate 320 and the air is sucked into the airbag 220 through the air hose 222 by the pumping of the rubber pump 390. Wrist-type digital sphygmomanometer comprising a).

The elastic member 240 is characterized in that the material of the span (span) material (stuff). The blood pressure measuring unit 200 is formed on the armband 210 and through the air hose 222 Wrist type digital blood pressure monitor further comprises an air supply unit 260 for manually supplying air to the airbag 220 and an exhaust unit 270 for manually discharging the air provided to the airbag 220. The blood pressure measuring unit 200 includes a resistor 280 whose resistance value changes according to the air pressure in the air bag 220, and the air injected into the air bag 220 according to the resistance value of the resistor 280. Wrist-type digital blood pressure monitor, characterized in that it further comprises a resistance value measuring circuit 290 for adjusting the amount.

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The airbag 220 and the air hose 222 is a wrist-type digital blood pressure monitor, characterized in that consisting of a urethane material.

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According to the present invention, by raising and lowering the piezoelectric sensor that protrudes from the armband in order to contact the radial artery of the wrist, it is possible to prevent the numbness and to accurately detect blood pressure.

According to the present invention, instead of swelling the entire wrist as in the conventional blood pressure monitor, by swelling only the part with the radial artery and pressing the radial artery, noise due to signal line shaking of the piezoelectric sensor can be reduced.

According to the present invention, motion artifacts can be reduced by reducing the shaking of the skin tissue by the airbag.

1 is a perspective view of a wrist-type digital blood pressure monitor according to the related art.

2 is a block diagram of a pressure sensor according to the related art.

3 is a perspective view of a wrist-type digital blood pressure monitor according to an embodiment of the present invention.

Figure 4 is a block diagram of a wrist-type digital blood pressure monitor according to an embodiment of the present invention.

5 is a view for explaining the operation of the piezoelectric sensor of the wrist-type digital blood pressure monitor according to an embodiment of the present invention.

6 is a graph showing the relationship between the voltage output in response to the pressure detected by the piezoelectric sensor according to the embodiment of the present invention.

Figure 7 is an exploded perspective view of the blood pressure measuring unit of the wrist-type digital blood pressure monitor according to the embodiment of the present invention.

8 is a diagram illustrating a manual airbag mechanism according to an embodiment of the present invention.

9 is a diagram illustrating an automatic airbag mechanism according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS

100: digital sphygmomanometer body 200: blood pressure measuring unit

110: microcomputer 120: power supply

130: operation unit 140: display unit

150: memory 160: motor pump

210: armband 211: band tops

212: lower band 220: airbag

222: air hose 230: piezoelectric sensor

240: stretchable member 250: FPCB

260: air supply unit 270: exhaust unit

280: resistor 290: resistance measurement circuit

Hereinafter, with reference to the accompanying drawings, the configuration and operation of the wrist-type digital blood pressure monitor according to an embodiment of the present invention will be described in detail.

According to an embodiment of the present invention, a piezoelectric sensor is disposed on a predetermined portion of an upper part of an airbag, and the wrist-type digital blood pressure monitor capable of measuring blood pressure by contacting the radial artery of the wrist after raising the upper part in response to the expansion of the airbag is provided. do.

3 is a perspective view of a wrist-type digital blood pressure monitor according to an embodiment of the present invention.

Referring to FIG. 3, the wrist-type digital blood pressure monitor according to the exemplary embodiment of the present invention includes a digital blood pressure monitor main body 100 and a blood pressure measuring unit 200, and the digital blood pressure monitor main body 100 includes an operation unit 130 and a display unit. 140, wherein the operation unit 130 may be a button, and the display unit 140 may be an LCD display window. In addition, the blood pressure measuring unit 200 may include a band 210, an airbag 220, a piezoelectric sensor 230, an elastic member 240, a resistor 280, and the like.

The digital sphygmomanometer main body 100 stores information on the blood pressure measured by the blood pressure measuring unit 200 in a memory or displays it on the LCD display window 140.

Blood pressure measuring unit 200 measures the blood pressure by raising the position of the piezoelectric sensor 230 in contact with the radial artery of the wrist during blood pressure measurement of the human body.

The arm 210 of the blood pressure measuring unit 200 is connected to the digital blood pressure monitor body 100, and serves to press the wrist.

The airbag 220 is installed on the armband 210 and expands in response to the air injected through the air hose 222. Here, the airbag 220 and the air hose 222 may be a urethane material.

The resistor 280 is disposed below the airbag 220, and contacts the lower portion of the fixed arm 210 in response to the expansion of the airbag 220. The air pressure of the airbag 220 may be adjusted by outputting a control signal corresponding to the changed resistance value.

The piezoelectric sensor 230 is disposed above the airbag 220, rises upward in response to the inflation of the airbag 220, and measures blood pressure by contacting the radial artery of the wrist. That is, the piezoelectric sensor 230 may be raised or lowered in the vertical direction in response to the expansion of the airbag 220, and the position may be adjusted in the horizontal direction in correspondence with the radial artery position of the wrist.

The stretchable member 240 is disposed above the piezoelectric sensor 230 and stretched according to the rising of the piezoelectric sensor 230, and the stretchable member 240 is made of a span material having good elasticity. May be).

On the other hand, Figure 4 is a view for explaining the operation of the piezoelectric sensor of the wrist-type digital blood pressure monitor according to an embodiment of the present invention.

Referring to FIG. 4, the wrist-type digital blood pressure monitor according to the embodiment of the present invention is a state in which the piezoelectric sensor 230 is not raised before the blood pressure is measured and is not in contact with the radial artery of the wrist. In order to measure blood pressure, air is injected into the airbag 220 through the air hose 222, and the airbag 220 expands to raise the piezoelectric sensor 230 disposed above the airbag 220 in the vertical direction. Contact the radial artery of the wrist.

At this time, the piezoelectric sensor 230 may be adjusted to move in the horizontal direction because the thickness of the wrist or the position of the radial artery may be different for each wearer.

Therefore, after the blood pressure is measured using the piezoelectric sensor 230, the piezoelectric sensor 230 returns to its original position by discharging the air in the airbag 220.

On the other hand, Figure 5 is a block diagram of a wrist-type digital blood pressure monitor according to an embodiment of the present invention.

Referring to FIG. 5, FIG. 5 illustrates a wrist-type digital sphygmomanometer including a digital sphygmomanometer body 100 and a blood pressure measuring unit 200, and the digital sphygmomanometer body 100 includes a microcomputer 110. The power supply unit 120 may include, but is not limited to, a power supply unit 120, an operation unit 130, a display unit 140, a memory 150, and a motor pump 160.

First, when power is applied to the power supply unit 120, the blood pressure is measured through the piezoelectric sensor 230 in the blood pressure measuring unit 200.

Here, the blood pressure measuring unit 200 discharges the air provided to the airbag 220 and the airbag 220 to provide air to the airbag 220 through the air hose 222 when the blood pressure is measured. An exhaust unit 270 may be included, and the air supply unit 260 and the exhaust unit 270 are formed on the armband 210, and are manually connected to the air bag 220 through the air hose 222. The air may be provided and discharged, and may also be supplied and discharged to the airbag 220 through the air hose 222 automatically by using a micro pump installed in the blood pressure monitor body 100.

Data corresponding to the blood pressure measured by the blood pressure measuring unit 200 is transmitted to the FPCB 250 through the FPCB signal line 232 connected to the piezoelectric sensor 230, these signals are microcomputer in the digital blood pressure monitor main body 100 The memory 110 may be stored in the memory 150 through 110 or displayed through the display 140.

The microcomputer 110 is controlled by manipulation of a button of the operation unit 130 installed outside the housing, and compares and analyzes the information about the blood pressure detected by the piezoelectric sensor 230 with the information previously stored in the memory 150 to maintain a health state. It serves to extract.

Further, the operation unit 130 may be a button type switch module provided with more than one connected switches, each of which is connected to a resistor.

The display unit 140 displays information on blood pressure output from the microcomputer 110.

The memory 150 stores information on a symptom or a health state according to the state of blood pressure, and stores information on blood pressure detected by the piezoelectric sensor 230. In addition, a predetermined program is stored in the memory 150, and such a program analyzes the blood pressure information measured under the control of the microcomputer 110 so that a user may know and compare it with a health state.

The motor pump 160 may be installed in the digital blood pressure monitor body 100 to inject air into the airbag 220.

The piezoelectric sensor 230 includes an amplifier and a bridge type sensor, and the result detected by the piezoelectric sensor 230 may be amplified by the amplifier, and the voltage may be output by the bridge type sensor. The bridged sensor is also connected to an analog / digital conversion unit having a plurality of amplifiers, resistors, and capacitors. Since the circuit of these electronic devices is the same as a general analog / digital conversion circuit, the structure thereof is not described here.

Specifically, in the wrist-type digital blood pressure monitor according to the embodiment of the present invention, for example, the power supply unit 120 may use a 3.7V lithium ion or lithium polymer battery. In addition, the measurement time of the wrist-type digital blood pressure monitor is 30sec, the measurement range is 0 ~ 280mmHg blood pressure. In addition, the pressure of the airbag 220 is measured at a pressure of 80 ~ 100mmHg, wherein the pressure may be calculated as the resistance value of the resistor. Here, since the calculation of the resistor is the same as that of a general analog / digital conversion circuit, the structure thereof is not described here.

Operation of the wrist-type digital blood pressure monitor according to an embodiment of the present invention is as follows.

First, the display unit 140, which is the LCD front panel, is worn on the wrists toward the palm of the hand, and the power unit 120 is pressed to turn on the power. Next, the hand that is not measuring blood pressure is slightly fisted and placed under the arm under measurement. Next, when the button operation unit 130 is lightly pressed, the motor pump 160 is operated, and the airbag 220 in the arm 210 is inflated accordingly while the motor pump 160 is maintained for about 30 seconds. The piezoelectric sensor 230 measures systolic blood pressure and diastolic blood pressure.

Thereafter, the blood pressure measured on the display unit 140 is displayed as systolic blood pressure and diastolic blood pressure. Next, the motor pump 160 is automatically turned off after 30 seconds due to the timer operation.

6 is a graph showing the relationship between the voltage output in response to the pressure detected by the piezoelectric sensor according to the embodiment of the present invention.

Referring to FIG. 6, the piezoelectric sensor according to the exemplary embodiment of the present invention outputs a voltage in response to the detected pressure, for example, converts a voltage of 0 to 8 V in response to a pressure in the range of 0 to 10 g / cm 2. Show output. Subsequently, the microcomputer 110 compares the converted voltage with the data stored in the memory 150 and outputs the corresponding blood pressure, that is, systolic blood pressure and diastolic blood pressure on the display unit 140.

On the other hand, Figure 7 is an exploded perspective view of the blood pressure measuring unit of the wrist-type digital blood pressure monitor according to an embodiment of the present invention.

Referring to FIG. 7, the blood pressure measuring unit 200 of the wrist-type digital blood pressure monitor according to the embodiment of the present invention includes a band upper plate 211, an air bag 220, a piezoelectric sensor 230, an elastic member 240, and It includes a band lower plate 212, the band lower plate 212 is formed of a rigid material supporting the air bag 220, the band upper plate 211 is combined with the band lower plate 212 to form a housing, A predetermined portion is opened so that the piezoelectric sensor 230 and the elastic member 240 rise. Here, reference numeral A denotes a portion where the expansion and contraction member 240 is opened, and reference numeral B denotes a predetermined portion of the upper portion of the airbag 220 in which the piezoelectric sensor 230 is disposed.

8 is a diagram illustrating a manual airbag mechanism according to an embodiment of the present invention.

Referring to FIG. 8, the manual airbag mechanism for manually injecting and discharging air into the airbag 220 according to the exemplary embodiment of the present invention presses the air supply unit 260 to inject air into the airbag 220. That is, the air is injected in the same principle as the pump.

In addition, when the exhaust unit 270 is pressed, the blocked hole is opened and air is discharged from the airbag 220 to the outside.

9 is a diagram illustrating an automatic airbag mechanism according to an embodiment of the present invention.

Referring to FIG. 9, the automatic airbag mechanism for automatically injecting and discharging air into the airbag 220 according to an embodiment of the present invention may include a resistance value measuring circuit 290 and micro pumps 260 and 270. For example, the micropump may be disposed within the digital sphygmomanometer body. For convenience, since the micropump includes both the air supply unit 260 and the exhaust unit 270, the same reference numerals will be used.

The resistance value measuring circuit 290 may adjust the amount of air injected into the airbag 220 in response to the resistance value of the resistor 280 changed according to the air pressure in the airbag 220. , 270).

The configuration of the wrist-type blood pressure monitor micropumps 260 and 270 includes a motor 370 in which rotational force is provided and an eccentric rotation shaft 371 is formed, and the motor 370 is coupled to discharge compressed air. The upper plate 380, the discharge port is formed in the upper plate 380 by the eccentric rotation shaft 371 of the motor 370 is installed to be lifted and lowered to exhaust the compressed air at one end The rubber pump 390 in which the valve 391 is formed, the lower plate 320 coupled to the upper plate 380 to be kept airtight, and having a suction port input by the rubber pump 390, and the lower portion thereof. It may be installed in the middle of the plate 320 may include a suction valve 310, the air is sucked by the pumping of the rubber pump 390.

The action of the wrist-type blood pressure monitor micropump having the above-described configuration is performed as follows.

First, when the eccentric rotation shaft 371 rotates by the operation of the motor 370, the upper portion of the rubber pump 390 is inserted and protruded downward by the eccentric rotation shaft 371 to move up and down to pump.

When the rubber pump 390 moves upward by the rotation of the motor 370, the intake valve 310 is opened by the pressure inside the pump to suck outside air.

When the rubber pump 390 moves downward by the rotation of the motor 370, the air filled between the rubber pump 390 and the lower plate 320 is compressed, so that the suction valve 310 As the exhaust valve 391 is opened while being closed, air is supplied to the airbag 220 of the blood pressure monitor through the connected rubber hose 222.

The above process is continuously repeated by the rotation of the motor 370, and the pumping is performed in a state of preventing air leakage.

Therefore, when a control signal is applied to the air supply unit 260 and the exhaust unit 270 according to an embodiment of the present invention, the air supply unit 260 first injects air into the arm 210 to apply pressure to a certain level. After the pressure is applied, the exhaust part 270 gradually discharges air.

During this operation, the piezoelectric sensor 230 transmits the pressure measured from the armband 210 to the oscillator in the FPCB 250 so that the oscillator oscillates in response to the measured pressure. The microcomputer 110 uses vibration of the oscillator. ) Detects and stores the blood pressure of the patient in the memory 150.

As a result, according to the embodiment of the present invention, after the piezoelectric sensor is raised upward in response to the inflation of the airbag, the blood pressure may be measured by contacting the radial artery of the wrist, thereby preventing numbness and accurately measuring blood pressure. Will be.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and it is common in the art that various substitutions, modifications, and changes can be made without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

Claims (10)

delete delete In order to measure blood pressure, the airbag 220 is connected to the blood pressure monitor body 100 and presses the wrist 210 and the air bag 220 installed on the arm 210 and inflated by the air injected through the air hose 222. And a piezoelectric sensor 230 disposed above the airbag 220 and measuring the blood pressure of the radial artery by rising or falling by the expansion and contraction of the airbag 220, and a band for supporting the airbag 220. The lower plate 212 and the elastic member 240 is disposed on the upper portion of the piezoelectric sensor 230 and stretched according to the rising of the piezoelectric sensor 230 and the band lower plate 212 to form a housing and A blood pressure measuring unit 200 having a band upper plate 211 having an open shape in which the piezoelectric sensor 230 and the elastic member 240 are cut out so that only the radial artery portion rises; And Memory 150 for storing blood pressure information measured by the blood pressure measuring unit 200, a display unit 140 for displaying the measured information, and air to the air bag 220 through the air hose 222 It includes a blood pressure monitor body 100 having a micro pump for injecting, The micro-pump includes a motor 370 that provides rotational power and has an eccentric rotation shaft, an upper plate 380 having an outlet for discharging compressed air to which the motor 370 is coupled, and the upper plate 380. Elevated and lowered by the eccentric rotation shaft 371 of the motor 370 is installed inside the exhaust valve 391 for discharging the compressed air in the air bag 220 through the air hose 222 at one end ) Is formed in the rubber pump 390, the lower plate 320 is coupled to maintain the airtight with the upper plate 380, the suction port is input by the rubber pump 390, and the lower plate 320 Wrist-type digital sphygmomanometer, characterized in that it comprises a suction valve 310 is installed in the middle and the air is sucked into the air bag 220 through the air hose (222) by the pumping of the rubber pump (390). The method of claim 3, wherein the stretching member 240, Wrist-type digital sphygmomanometer, characterized in that consisting of a span (stuff) material (stuff). delete According to claim 3, The blood pressure measuring unit 200, The air supply unit 260 is formed on the armband 210 and manually supplies air to the airbag 220 through the air hose 222, and a ship for manually discharging the air provided to the airbag 220 Wrist type digital sphygmomanometer, characterized in that it further comprises a base (270). delete According to claim 3, The blood pressure measuring unit 200, A resistance value measuring circuit 290 for adjusting the amount of air injected into the airbag 220 according to the resistance value of the resistor 280 and the resistance value of the resistor 280 that changes in resistance according to the air pressure in the airbag 220. Wrist-type digital sphygmomanometer, characterized in that it further comprises). delete The method of claim 3, The airbag 220 and the air hose 222 is a wrist-type digital blood pressure monitor, characterized in that consisting of a urethane material.