KR200190075Y1 - Electronic sphygmomanometer - Google Patents

Abstract

The present invention proposes an electronic pulse sphygmomanometer comprising a pair of cuffs with arterial blood bags, two pressure sensors, and a control circuit. The circuit circuit portion is formed by connecting a microprocessor, a motor, an air pressure loop, a contraction member, a display, a button, a power supply circuit, and two measurement circuits. Pressure sensors are installed in each cuff. Two pressure sensors are respectively connected to the measurement circuits of the control circuit section. Thus, the electronic pulse sphygmomanometer of the present invention has both the advantages of the stethoscope method and the oscillometric method of using the measuring sensor to increase the measurement accuracy.

Description

Electronic sphygmomanometer

The present invention relates to an electronic pulse sphygmomanometer, and more particularly, to an electronic pulse sphygmomanometer for measuring blood pressure (heart contraction pressure and diastolic pressure) using two cuffs.

Auscultation methods and oscillometric methods are the most widely used methods for the clinical measurement of cardiac contraction and diastolic pressure.

In the stethoscope method, the cuff is wrapped around the upper arm and then pressure is applied and the stethoscope is placed in front of the elbow. If the pressure in the cuff is too small, the blood easily fills the artery. Even if there is a pulse, the stethoscope will not hear anything. However, if the pressure in the cuff 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 Korotkoff sound.

To measure blood pressure using the auscultation method, first apply pressure to the cuff at a pressure higher than the arterial contraction pressure. The arteries of the arm will compress and block the blood flow. Korotkoff will not be heard. When the pressure in the cuff decreases slightly below the heart contraction pressure of the artery, some blood will flow through the blood vessel under the cuff. You'll hear a tap sound in sync with the heartbeat in the artery in front of the elbow. At the same time as the sound is heard, the pressure detected by the pressure sensor connected to the cuff is read. This is almost the same as the heart contraction pressure.

The stethoscope method has the advantage of high accuracy. Stethoscopes, however, cannot be used by non-specialists because they are used to monitor Korotkoff sounds, a basic skill for professionals. Therefore, this method is rarely used at home.

The oscillometric method uses electronic sensors to detect arterial blood vessel waveforms and evaluates high and low pressures using experimental parameters. The oscillometric method has the advantage that the measurement is convenient and portable. However, high and low pressures are obtained according to the parameters evaluated. Although these parameters follow the characteristics of most users, they are not applicable to some special users, such as atherosclerosis and diabetics. In addition, the probability of error will increase due to the evaluation.

Moreover, conventional electronic pulse sphygmomanometers measure blood pressure through cuffs having an aeration bag matched to a circuit control in the electronic pulse sphygmomanometer. The benefits of the stethoscope method and the benefits of the oscillometric method cannot be obtained at the same time, so that no particular accuracy can be increased.

The main object of the present invention is to provide an electronic pulse sphygmomanometer having a pair of cuffs, in which a pressure sensor is installed in each cuff having an arterial blood bag. Each pressure sensor is connected to a specific circuit of a circuit controller in the electronic pulse sphygmomanometer. The measuring circuit is connected to the microprocessor. The microprocessor is connected to a power supply circuit, a display, a button, a motor, and a contraction member for contraction of the arterial blood bag, respectively. The motor and the shrink member are each connected to an air pressure loop for inflation of the arterialized bag. The air pressure loop is connected to two cuffs respectively. This allows the measurement accuracy to be increased efficiently.

Various objects and advantages of the present invention will be more readily understood from the following detailed description when read in conjunction with the accompanying drawings.

1 is a circuit block diagram of the present invention.

Figure 2 shows a pair of cuffs wound around the upper arm of the subject according to the present invention.

3 is an operation flowchart of the present invention.

Figure 4 shows the waveform when no signal is detected in the B cuff according to the present invention.

5 is a view showing a waveform when a pulse signal is detected in the B cuff according to the present invention.

6 is a view showing a waveform when a signal change is detected in the B cuff according to the present invention.

Explanation of symbols for the main parts of the drawings>

1: first cuff 2: second cuff

3: circuit control unit 11: first pressure sensor

21: second pressure sensor 31: microprocessor

32: button 33: power circuit

34: display 35: motor

36: air pressure loop 37: contraction member

38: first measurement circuit 39: second measurement circuit

As shown in Figs. 1 and 2, the electronic pulse sphygmomanometer according to the present invention includes a first cuff 1 having an arterial blood bag, a second cuff 2 having an arterial blood bag, and an electronic pulse sphygmomanometer. The control unit 3 is included.

The first pressure sensor 11 is installed in the first cuff 1 to detect a signal of blood flow in the artery.

The second pressure sensor 21 is installed in the second cuff 2 to detect a signal of blood flow in the artery.

The microprocessor 31 is installed in the circuit control unit 3. The power supply circuit 33 for supplying the operating power is connected to the microprocessor 31. The output port of the microprocessor 31 is connected to the display 34 for displaying the measured blood pressure value, the motor 35, and the contraction member 37 for contraction of the arterial blood bag. The motor 35 and the shrinkage member 37 are each connected to an air pressure loop 36. The outputs of the air pressure loop 36 are connected to the first cuff 1 and the second cuff 2, respectively. The air pressure loop 36 begins to press the arterial blood bag when the motor 35 is activated. The microprocessor 31 is connected to the button 32, the first measurement circuit 38, and the second measurement circuit 39. The measuring circuits 38 and 39 are connected to the first and second pressure sensors 11 and 21, respectively. The measuring circuit 38 (or 39) transmits a signal from the pressure sensor 11 (or 21) to the microprocessor 31 for next determination and processing.

3 shows an operation flowchart of the present invention. First, pressing the button (60) activates the contraction member (61) to complete the contraction of the arterialized bags of the first cuff and the second cuff. Next, the second cuff is pressed 62 to touch the artery by activating the motor 62 to activate the air pressure loop 63. At this time, the waveform of the arterial pulse detected by the pressure sensor in the B cuff is unchanged and uniform as shown in FIG. 4. The first cuff is joined until the artery is compressed (ie, until the pressure in the first cuff is above the minimum blood pressure) (65). At this time, the microprocessor will determine whether the pressure sensor in the second cuff senses the waveform change, as shown in FIG. If no signal is detected, jump back to step 62; otherwise, the pressure at which the waveform changes is the diastolic pressure. Next, the pressure of the first cuff is continuously lowered (67) until blood flow in the artery is blocked. At this time, as shown in FIG. 6, no blood flow in the artery will be detected by the pressure sensor in the second cuff (ie, the pressure in the first cuff is above the maximum blood pressure) 68. At the same time, the microprocessor will determine whether the signal sensed by the pressure sensor in the second cuff disappears (69). If the signal does not disappear, jump back to step 67; otherwise, cardiac contraction pressure and diastolic pressure will be displayed on display 70. The motor is then stopped (71) and the contraction member is activated (72) for complete contraction of the veneered bag of the first and second cuffs.

In summary, with the modified circuit, the electronic pulse sphygmomanometer of the present invention has both the advantages of the stethoscope method and the oscillometric method using the measuring sensor to increase the measurement accuracy.

While the present invention has been described with reference to the most preferred embodiments, it will be appreciated that this invention is not limited to its details. Various alternatives and modifications have been proposed in the foregoing description, and others will occur to those skilled in the art. Therefore, all such replacements and modifications are intended to be included within the scope of the present invention as defined in the appended claims.

Claims (3)

In an electronic pulse sphygmomanometer having both the advantages of the stethoscope method and the advantages of an oscillometric method using a measuring sensor, A first cuff having an aeration bag, the first cuff being installed to sense a signal of blood flow in the artery; A second cuff having an arterial blood bag and provided with a second pressure sensor to sense a signal of blood flow in the artery; An output port of the microprocessor is connected to a display for displaying the measured blood pressure value, a motor, and a contraction member for contraction of the arterialized bags, wherein the motor and the contraction member are each connected to an air pressure loop, and the air Outputs of the pressure loop are connected to the first and second cuffs respectively, the microprocessor is connected to a first measurement circuit and a second measurement circuit, and the measurement circuits are respectively connected to the first and second pressure sensors. And the measuring circuits comprise a circuit control unit in which the microprocessor is installed for transmitting signals from the pressure sensors to the microprocessor for subsequent determination and processing. The electronic pulse sphygmomanometer according to claim 1, further comprising a button connected to said microprocessor. The electronic pulse sphygmomanometer according to claim 1, wherein the circuit control unit can be installed in the electronic pulsometer.