KR20130065513A - Hemadynamometer using micsensor with display device - Google Patents

Abstract

The present invention relates to a blood pressure monitor, and more particularly, a microphone sensor and a display device using a microphone sensor and an LED to emit an LED according to the data sensed by the microphone sensor without a separate stethoscope, thereby enabling accurate blood pressure measurement by time of day. It relates to a blood pressure monitor using. The blood pressure monitor using the present invention microphone sensor and the display device includes a microphone sensor unit 10 for sensing a pulse sound and outputting it as an electric signal; LED sphygmomanometer 20 for displaying the highest blood pressure and the lowest blood pressure point of the blood pressure monitor 26 for measuring the highest blood pressure and the lowest blood pressure according to the electric signal transmitted from the microphone sensor unit 10; Cuff 30 for blocking the flow of blood through the arm for the highest blood pressure and the lowest blood pressure measurement; A pump 40 for injecting air into the cuff 30; A valve 50 for discharging the air injected into the cuff 30; A tube (70) for supplying air discharged from the valve (50) to the blood pressure monitor (26); And a blood pressure monitor case 60 for storing the blood pressure sphygmomanometer 20, the cuff 30, and the pump 40.

Description

Blood pressure monitor using microphone sensor and indicator lamp {Hemadynamometer using micsensor with display device}

The present invention relates to a blood pressure monitor, and more particularly, a microphone sensor and a display device using a microphone sensor and an LED to emit an LED according to the data sensed by the microphone sensor without a separate stethoscope, thereby enabling accurate blood pressure measurement by time of day. It relates to a blood pressure monitor using.

A typical mercury sphygmomanometer consists of a pump that supplies air to the cuff, a cuff that applies air to the upper arm, and a mercury bottle that measures the pressure.

When the pressure inside the cuff rises above the peak blood pressure that occurs in the systole, the flow of blood through the arm is completely blocked. Since the pressure of the cuff gradually decreases, if the pressure is located between the highest blood pressure of the systolic system and the lowest blood pressure of the diastolic body, the blood flows when the heart contracts and the blood flow is blocked again when it is relaxed.

The result is an unusual Korotkoff sound. When the cuff pressure is lower than the minimum blood pressure, the blood flows normally in the arm and the Korotkoff sound disappears.

The measurer must hear this pulse directly with a stethoscope to measure blood pressure. However, in case of severe ambient noise or hearing loss, it could be difficult to hear a minute pulse with a stethoscope.

Representative manual blood pressure monitors are similar to the mercury blood pressure monitor as shown in FIG. 1, the mercury blood pressure monitor as shown in FIG. 2, but the mercury blood pressure monitor as shown in FIG. And miniaturized arenoid blood pressure monitor using an aneroid barometer as shown in FIG.

The aneroid sphygmomanometer has a peculiar simplicity and portability as compared to a mercury sphygmomanometer, but it has greatly reduced the advantages of having to carry a stethoscope together.

On the other hand, the automatic blood pressure monitor is as shown in Figures 4 and 5, in the case of Figure 5 is a wrist-type blood pressure monitor. The automatic sphygmomanometer adopts a method of calculating blood pressure by measuring vibration of a pressure value detected by a pressure sensor connected to a cuff without using an analog pressure measurement method such as mercury or aneroid barometer.

Therefore, it is a suitable measurement method for non-skilled people, but inaccurate values tend to be measured in patients with heart disease or circulatory disease (arteriosclerosis, arrhythmia, etc.). It is known to have low accuracy.

In particular, in the case of a wrist-type blood pressure monitor, since the blood pressure tends to change greatly according to the position of the wrist, there is also a problem that the error of the measured value is larger than that of the measurement on the arm.

Accordingly, the present invention is to solve all the disadvantages and problems of the prior art as described above, the present invention by using the microphone sensor and the LED by the light emitting the LED according to the data sensed by the microphone sensor without a separate stethoscope The aim is to provide a blood pressure monitor using a microphone sensor and a display to enable accurate blood pressure measurement.

Another object of the present invention is to provide a blood pressure monitor using a microphone sensor and a display device capable of measuring blood pressure even by the hearing impaired by outputting the highest blood pressure and the lowest blood pressure through a separate voice output unit.

Blood pressure monitor using the present invention microphone sensor and the display device for achieving the above object, the microphone sensor unit for sensing the pulse sound and output as an electrical signal; LED sphygmomanometer 20 which displays the highest and lowest blood pressure points of the sphygmomanometer 26 for measuring the highest blood pressure and the lowest blood pressure according to the electric signal transmitted from the microphone sensor unit 10; Cuff 30 to block the flow of blood through the arm for the highest and lowest blood pressure measurement; A pump 40 for injecting air into the cuff 30; A valve 50 for discharging air injected into the cuff 30; A tube 70 for supplying air discharged from the valve 50 to the blood pressure monitor 26; And a blood pressure monitor case 60 for storing the blood pressure sphygmomanometer 20, the cuff 30, and the pump 40.

Here, the microphone sensor unit 10 is preferably composed of a diaphragm 11 for amplifying the detected pulse sound, and a condenser microphone 12 for receiving the amplified pulse sound and converting it into an electrical signal.

In addition, the LED blood pressure monitor 20 is turned on and off according to the signal processor 21 for removing and amplifying noise from the electrical signal output from the microphone sensor unit 10 and the electrical signal amplified and output from the signal processor 21. The display lamp 22 and the signal processor 21 and the control unit 24 for controlling the display lamp 22 are preferably configured to include a light emitting LED.

On the other hand, the LED blood pressure monitor 20 has a storage unit 23 for storing the highest blood pressure and the lowest blood pressure, a voice output unit 25 for audio output of the highest blood pressure and the lowest blood pressure, and the highest blood pressure and the lowest blood pressure of the blood pressure monitor 26 Preferably, the second signal processor 27 further includes a second signal processor 27 for processing a value corresponding to the data signal.

In addition, the valve 50 includes a valve handle 51 including a discharge port for reducing the pressure of the cuff 30, a panel with a valve handle 52 formed on one side of the outer circumferential surface of the valve handle 51, and a valve handle ( The valve handle pivoting stopper panel 54 and the valve knob pivoting stopper panel 54 which rotate in the direction which intersects 51 are comprised by the hinge 53 which serves as the axis which moves in a vertical direction, and the pressure of the cuff 30 is carried out. It is desirable to adjust the rate of reduction.

The present invention as described above has the following effects.

First, by using the microphone sensor and the LED can emit an LED according to the data sensed by the microphone sensor without a separate stethoscope so that accurate blood pressure measurement can be performed by visually in a noisy place such as an emergency room.

Second, the absence of a stethoscope can minimize hearing damage that can occur when the stethoscope is used a lot.

Third, the hearing impaired person can measure blood pressure by outputting the highest blood pressure and the lowest blood pressure through a separate voice output unit.

1 is a view showing a manual sphygmomanometer according to an example of the prior art,
2 is a view showing a manual blood pressure monitor according to another example of the prior art,
3 is a view showing a manual blood pressure monitor according to another example of the prior art,
4 is a view showing an automatic blood pressure monitor according to an example of the prior art,
5 is a view showing an automatic blood pressure monitor according to another example of the prior art,
6 is a block diagram of a blood pressure monitor using a microphone sensor and a display device according to the present invention;
7 is a perspective view illustrating a blood pressure monitor using a microphone sensor and a display device according to the present invention;
8 to 10 are views for explaining in detail the valve in the blood pressure monitor using the microphone sensor and the display device according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In addition, although the term used in the present invention is selected as a general term that is widely used at present, there are some terms selected arbitrarily by the applicant in a specific case. In this case, since the meaning is described in detail in the description of the relevant invention, It is to be understood that the present invention should be grasped as a meaning of a term that is not a name of the present invention. Further, in describing the embodiments, descriptions of technical contents which are well known in the technical field to which the present invention belongs and which are not directly related to the present invention will be omitted. This is for the sake of clarity of the present invention without omitting the unnecessary explanation.

6 is a block diagram illustrating a blood pressure monitor using the microphone sensor and the display device according to the present invention, and FIG. 7 is a perspective view illustrating the blood pressure monitor using the microphone sensor and the display device according to the present invention.

As shown in FIGS. 6 and 7, the blood pressure monitor using the microphone sensor and the display device according to the present invention includes the microphone sensor unit 10, the LED blood pressure monitor 20, the cuff 30, the pump 40, and the valve 50. ), A blood pressure monitor case 60 and a tube 70.

Here, the microphone sensor unit 10 is composed of a diaphragm 11 and a condenser microphone 12 to sense a pulse sound.

Here, the diaphragm 11 amplifies the sensed pulse sound.

The condenser microphone 12 receives the amplified pulse sound, converts it into an electrical signal, and outputs it to the LED blood pressure monitor 20.

That is, in order to convert the sound heard by the conventional stethoscope into the LED light signal, the microphone sensor unit 10 that first receives the sound signal is required. Such, the microphone sensor unit 10 should be able to catch the minute pulse sound, and at the same time it is preferable that the shape or size of the sensor does not affect the blood pressure measurement.

The LED blood pressure monitor 20 includes a first signal processor 21, a display lamp 22, and a controller 24 to turn on / off the display lamp 22 according to an electric signal transmitted from the microphone sensor unit 10. do. In addition, the storage unit 23, the voice output unit 25, the blood pressure monitor 26 and the second signal processing unit 27 may be further configured.

Here, the signal processor 21 removes and amplifies the noise from the electrical signal and outputs the amplified signal to the display lamp 22.

The display lamp 22 lights the lamp according to the electric signal amplified and transmitted by the signal processor 21. Such display lamps are preferably composed of high brightness LED lamps, and the number of the display lamps need not be particularly limited. That is, a large number is shown in the drawings, but this is for convenience of description.

The storage unit 23 stores the highest blood pressure and the lowest blood pressure of the blood pressure monitor 26 shown in FIG. At this time, it may be stored together with the date of the year, month, day, and time. Here, the blood pressure monitor 26 can be configured with a mercury bottle measuring the pressure. And, hypertension patients may need periodic measurement and monitoring of blood pressure. If the measured blood pressure is stored according to the date and time, and the data can be managed by a computer, it will be helpful to understand the trend of blood pressure change and to perform the correct medical treatment.

When the display lamp 22 is turned on after the signal processed by the signal processor 21 exceeds the set threshold value (removing unnecessary noise signal), the controller 24 may turn off the highest blood pressure value and turn off time of the corresponding lighting time point (pulse pulse time point). The minimum blood pressure value (the time when the pulse does not run) is controlled to be stored in the storage unit 23.

In addition, the controller 24 may control to output the highest blood pressure value and the lowest blood pressure value through the voice output unit 25. In this case, the visually impaired may also measure blood pressure. To this end, it is preferable to further configure a second signal processing unit 27 for processing a signal for the highest blood pressure value from the blood pressure monitor 26 and the measured value of the lowest blood pressure value as a data signal.

On the other hand, the cuff 30 is to completely block the flow of blood through the arm in order to measure the blood pressure, and wound around the human arm through the adhesive member 31.

The pump 40 injects air into the cuff 30 to block the flow of blood through the cuff 30. Briefly, if the pressure inside the cuff 30 is higher than the maximum blood pressure generated in the systolic system, the flow of blood through the arm is completely blocked. Since the pressure of the cuff 30 is gradually reduced, if the position between the highest blood pressure of the systolic system and the lowest blood pressure of the diastolic, the blood flows when the heart contracts, the blood flow is blocked again when relaxed. The result is an unusual Korotkoff sound. After the pressure of the cuff 30 is lower than the minimum blood pressure, the blood flows normally in the arm, the pulse sound disappears.

At this time, the LED is mounted on the blood pressure monitor so that the sound of the pulse can be seen by the eye, and thus the blood pressure can be measured only visually without a stethoscope.

On the other hand, not needing a stethoscope means not only having to buy a stethoscope, but also means that the operator doesn't have to hear pain and noise when using the earpiece in the stethoscope. Above all, of course, the blood pressure measurement process is simplified.

The valve 50 gradually discharges the air injected into the cuff 30. In general, the pressure of the cuff 30 should be gradually decreased after the pressure of the cuff 30 rises more than the maximum blood pressure in order to determine a section in which a pulse sound is heard while measuring blood pressure.

At this time, in the process of opening the valve 50 of the pump 40 connected to the cuff 30, excessively open the valve 50, the pressure of the cuff 30 is sharply reduced to prevent the blood pressure can be properly measured do.

In order to prevent this, the present invention has developed a valve 50 in which the valve 50 does not open excessively during blood pressure measurement. For example, a drop of 2 to 3 mmHg per second can help to make blood pressure measurements more accurate.

8 to 10 are views for explaining in detail the valve in the blood pressure monitor using the microphone sensor and the display device according to the present invention.

In the blood pressure monitor using the microphone sensor and the display device according to the present invention, as shown in FIGS. 8 to 10, the valve handle 51, the valve handle attaching panel 52, the hinge 53, and the valve handle pivoting stopper panel ( 54). In general, the diameter of the outlet of the valve 50 is very small (0.7 mm), but because the pressure in the cuff 30 is large, the air can be discharged quickly if fully opened.

In a typical measurement, the ideal rate of pressure reduction is about 2 to 3 mmHg per second. To slow down the pressure slowly, the valve must be opened only slightly (experimentally, the valve handle with a diameter of 1.2 cm must be turned within a 20 degree angle from the fully closed position. did). For this reason, if the valve is turned over 20 degrees by mistake during the measurement, air is suddenly discharged, and accurate blood pressure measurement is difficult.

In order to prevent this, in this invention, the valve 50 comprises the valve handle 51, the panel with a valve handle 52, the hinge 53, and the valve handle rotation stopper panel 54. As shown in FIG. 8 to 10, the valve knob 51 is not rotated at an angle of 20 degrees or more, for example, and when the time comes to measure the minimum blood pressure and quickly remove the air, the measurer hinges the handle pivot stopper panel 54. It is shown that the valve knob 51 can be completely opened by adjusting (rotating down) the reference numeral 53 as the axis.

When the valve 50 is made of the valve handle 51, the valve handle panel 52, the hinge 53, and the valve handle pivot stopper panel 54 in this manner, the measurer does not have to worry about not opening the valve excessively. This will allow you to focus on measuring your blood pressure.

On the other hand, the blood pressure monitor case 60 is composed of a space 61 for storing the LED blood pressure monitor 20, the cuff 30 and the pump 40.

While the present invention has been described with reference to the exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. Therefore, the examples disclosed in the present invention are not intended to limit the scope of the present invention and are not intended to limit the scope of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: microphone sensor unit 11: diaphragm
12: microphone condenser 20: LED blood pressure monitor
21: signal processor 22: display lamp
23: voice output unit 24: control unit
25: storage unit 26: blood pressure monitor
30: cuff 31: adhesive portion
40: pump 50: valve
51: valve handle 52: panel with valve handle
53: hinge 54: valve handle rotating stopper panel
60: blood pressure monitor case 61: blood pressure monitor storage
70: tube

Claims (5)

A microphone sensor unit 10 for sensing a pulse sound and outputting the electric signal;
LED sphygmomanometer 20 for displaying the highest blood pressure and the lowest blood pressure point of the blood pressure monitor 26 for measuring the highest blood pressure and the lowest blood pressure according to the electric signal transmitted from the microphone sensor unit 10;
Cuff 30 for blocking the flow of blood through the arm for the highest blood pressure and the lowest blood pressure measurement;
A pump 40 for injecting air into the cuff 30;
A valve 50 for discharging the air injected into the cuff 30;
A tube (70) for supplying air discharged from the valve (50) to the blood pressure monitor (26); And
Sphygmomanometer using a microphone sensor and a display, characterized in that it comprises a; blood pressure sphygmomanometer 20, the cuff 30 and the blood pressure monitor case (60) for storing the pump (40).
The method of claim 1,
The microphone sensor unit 10 includes a diaphragm 11 for amplifying the detected pulse sound and a condenser microphone 12 for receiving the amplified pulse sound and converting the converted pulse into an electrical signal. Sphygmomanometer using.
The method of claim 1,
The LED blood pressure monitor 20 is a signal processing unit 21 for removing and amplifying noise from the electrical signal output from the microphone sensor unit 10,
A display lamp 22 composed of a light emitting LED that is turned on and off according to an electric signal amplified and output by the signal processor 21;
Blood pressure monitor using a microphone sensor and a display device, characterized in that it comprises a control unit 24 for controlling the signal processor 21 and the display lamp (22).
The method of claim 3,
The LED blood pressure monitor 20
A storage unit 23 for storing the highest blood pressure and the lowest blood pressure;
An audio output unit 25 for outputting the highest blood pressure and the lowest blood pressure as voice;
Sphygmomanometer using a microphone sensor and a display device further comprises a second signal processing unit (27) for processing the values corresponding to the highest blood pressure and the lowest blood pressure of the blood pressure monitor (26) as a data signal.
The method of claim 1,
The valve 50,
A valve handle 51 including an outlet for reducing the pressure of the cuff 30,
A valve handle attaching panel 52 formed at one side of an outer circumferential surface of the valve handle 51;
A valve handle pivot stopper panel 54 pivoting in a direction intersecting with the valve knob 51 and
The valve handle pivotal stopper panel 54 is composed of a hinge 53 that serves as an axis to move in the vertical direction,
Blood pressure monitor using a microphone sensor and a display device, characterized in that for adjusting the pressure reduction rate of the cuff (30).

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