KR0133448B1 - Sphygmomanometer having control function for optimum pressing and control metod thereof - Google Patents

Abstract

A key input unit 21 for a user to input a command; A sensor 22 which detects the air pressure and pulse wave of the conduit and converts it into an electrical signal and outputs the electrical signal; A microcontroller 23 for outputting a control signal for fine exhaust according to a command input from a key input / output unit, measuring blood pressure using a signal input from a sensor, and then outputting an information signal for displaying it externally; ; A pressurizing section 25 for driving the air pressure in the conduit by driving when a control signal is input from the microcontroller; An air tank 28 and a buffer 29 for temporarily storing the air pressure transmitted from the pressurizing unit; A solenoid valve 26 which turns on and off when a control signal is input from the microcontroller to exhaust the air in the conduit to the outside; Compression table 27 for transmitting the pulse wave generated from the human body to the sensor; A display section 24 for displaying the blood pressure externally in accordance with the information signal input from the microcontroller; The present invention relates to a blood pressure monitor having an optimal pressure control function which provides comfort to the subject by measuring the blood pressure by stopping the driving of the pressurization means at a pressure capable of measuring blood pressure after analyzing the arterial pressure of the subject.

Description

Sphygmomanometer with optimal pressure control and its control method

1 is a block diagram of a conventional blood pressure monitor,

2 is a blood pressure measurement waveform diagram of a conventional blood pressure monitor,

3 is a block diagram of a blood pressure monitor having an optimum pressure control function according to an embodiment of the present invention,

4 is an operation flowchart of a control method of a blood pressure monitor having an optimum pressure control function according to an embodiment of the present invention,

5 is a waveform chart of the measurement of the pressure of the blood pressure monitor when there is no tank and the buffer of the blood pressure monitor having an optimum pressure control function according to an embodiment of the present invention,

6 is a measurement waveform chart when pressurized when there is only a tank of a blood pressure monitor having an optimum pressure control function according to an embodiment of the present invention,

7 is a waveform diagram of measurement at pressurization when both the tank and the buffer of the blood pressure monitor having the optimum pressure control function according to the embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

11,21: key input 12,22: sensor

13,23: microcontroller 14,24: display unit

15,25: pressure portion 16,26: solenoid valve

17: fine exhaust valve 18, 27: pressure bar

28: air tank 29: buffer

The present invention relates to a blood pressure monitor having an optimal pressure control function and a control method thereof. More specifically, the blood pressure is measured by stopping the driving of the pressurizing means at a pressure capable of measuring blood pressure after extracting and analyzing arterial pressure of the subject. The present invention relates to a blood pressure monitor having an optimum pressure control function that can give comfort to a measurer, and a control method thereof. Blood pressure is a medically important factor as a criterion for judging a person's health.

In the hospital, to check the blood pressure of the patient, the pressure band is wound on the forearm of the patient and then pumped so that the pressure band is in close contact with the forearm of the patient. Sphygmomanometers for measuring human blood pressure by processing through a circuit are generally used.

In recent years, as the public's interest in health increases, portable sphygmomanometers which can easily measure blood pressure without going to the hospital have been widely marketed for commercial purposes. As described above, a technique related to a portable blood pressure monitor has been disclosed in a Korean portable blood pressure monitor of Korean Patent Application No. 93-24242 (filed date: November 15, 1993). Hereinafter, a conventional blood pressure monitor will be described with reference to the accompanying drawings.

1 is a block diagram of a conventional blood pressure monitor.

As shown in FIG. 2, a conventional blood pressure monitor includes a key input unit 11, a microcontroller 13 having an input terminal connected to an output terminal of the key input unit 11, and an output terminal of the micro controller 13 described above. The pressurizing part 15 to which the input end is connected, the sensor 12 connected to the pressurizing part 15 through a conduit, the solenoid valve 16, the fine exhaust valve 17, the press table 18, and It consists of a display unit 14 having an input terminal connected to an output terminal of the microcontroller 13. The operation of the conventional blood pressure monitor according to the above configuration is as follows.

When power is applied by mounting a battery, the operation of a conventional blood pressure monitor is started. When the user inputs an operation command using the key input unit 11 after the operation is started, the microcontroller 13 detects this and drives the pressing unit 15 to generate air pressure from the pressing unit 15 through the conduit. The sensor 12 and the solenoid valve 16 and the fine exhaust valve 17 and the pressure plate 18 to be delivered.

In this case, the solenoid valve 16 is closed, and since the small amount of air pressure can flow out through the fine exhaust valve 17, most of the air pressure generated from the pressurizing portion 15 is the pressure bar. It is transmitted to (18) to allow the compression table 18 to tighten the human body (forearm).

The human body portion tightened by the pressing table 18 increases the blood pressure, and when the pressure is increased to a predetermined pressure or more, the microcontroller 13 stops driving the pressing unit 15.

When the driving of the pressurization unit 15 is stopped, while the air pressure inside the conduit is reduced by the air pressure discharged through the fine exhaust valve 17, the pulsation of the blood pressure transmitted from the human body is transmitted through the air in the conduit and the sensor ( 12). The sensor 12 converts the pulsation transmitted through the conduit into an electrical signal and then outputs it to the microcontroller 13. Thus, the waveform of the pulsation output from the sensor 12 to the microcontroller 13 is shown in FIG. 2 is a blood pressure measurement waveform diagram of a conventional blood pressure monitor.

The microcontroller 13 calculates the blood pressure from the pulsation signal input from the sensor 12 and then displays it externally through the display unit 14 so that the user can know the blood pressure.

After the blood pressure measurement, the microcontroller 13 opens the solenoid valve 16 so that the high-pressure air contained in the conduit is quickly exhausted to the outside to make the user feel comfortable.

However, the conventional blood pressure monitor uses the air pressure generated from the pressurizing unit 15 at the initial stage of operation to the pressure at which the microcontroller 13 is preset in the process of tightening the human body (forearm). As the pressure increases uniformly, the subject feels different pressure depending on the body type and the blood pressure state of the subject. There are disadvantages.

In addition, since the conventional blood pressure monitor pressurizes to an unnecessary pressure, there is a problem that power consumption of the performed battery may be generated and the overall measurement time may be delayed.

Accordingly, an object of the present invention is to solve the above-mentioned disadvantages and problems, by extracting and analyzing the arterial pressure of the subject, and stopping the driving of the pressurizing means at a pressure capable of measuring blood pressure to measure the blood pressure. It is to provide a blood pressure monitor having an optimum pressure control function and a control method thereof that can give comfort.

As a means for achieving the above object, the configuration of the present invention comprises a key input unit for a user to input a command, a sensor for detecting the air pressure and pulse wave of the conduit, and converting it into an electrical signal and outputting the same; A microcontroller for outputting a control signal for fine exhaust according to a command input from a key input unit, measuring a blood pressure using a signal input from the sensor, and then outputting an information signal for external display of the blood pressure; When a control signal is input from a microcontroller, a pressurizing unit pressurizes the air pressure in the conduit, an air tank and a buffer for temporarily storing the air pressure transmitted from the pressurizing unit, and a control signal is input from the microcontroller. A solenoid valve that exhausts air in the conduit to the outside by turning on and off, and Depending on the cuff and the information signal input from the above-mentioned microcontroller for transmitting the pulse waves to the sensor resulting from comprises a display unit for displaying the blood pressure on the outside.

As another means of achieving the above object, another configuration of the present invention is to open the solenoid valve while the operation is started when the battery is mounted, to maintain the low power use mode after initializing the internal memory variable, the key input unit Determining whether the power switch is turned on, determining whether there is a key input when the power switch is turned on, terminating the operation when there is no key input for a predetermined time, and when the key is input, After closing, driving the pressurizing unit to increase the air pressure, averaging the changed air pressure, detecting and storing the pulse wave transmitted from the human body, determining whether the highest blood pressure is detected, and when the highest blood pressure is detected. Further pressurizing a predetermined pressure to stop the pressurizing, and Thereafter, the blood pressure is measured while finely evacuating to detect the highest blood pressure and the lowest blood pressure, displaying the high / low pressure and the pulse of the blood pressure, and ending the operation while rapidly exhausting by opening the solenoid valve.

By the above configuration, the most preferred embodiment that can be easily carried out by those skilled in the art with reference to the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 3, the configuration of the blood pressure monitor having the optimum pressure control function according to the embodiment of the present invention includes a microcontroller having an input terminal connected to the key input unit 21 and the output terminal of the key input unit 21 described above. 23, an air tank 28 connected to the pressurizing portion 25 to which the input end is connected to the output end of the microcontroller 23, the pressurizing portion 25 through a conduit, and an air tank 28 A buffer 29 connected through a conduit, a sensor 22 connected to the buffer 29 via a conduit, a solenoid valve 26, a pressure bar 27, and an output end of the microcontroller 23 described above. The display unit 24 is connected to the input terminal.

The air tank 28 is made of a soft rubber material.

4 is a flowchart illustrating a method of controlling a blood pressure monitor having an optimal pressure control function according to an embodiment of the present invention. As shown in Figure 4, the configuration of the control method of the blood pressure monitor having the optimum pressure control function according to an embodiment of the present invention, the operation is started when the battery is mounted (S10), and the step of opening the solenoid valve (S120) ), Initializing the internal memory variable (S30), maintaining the low power usage mode (S40), determining whether the power switch is turned on from the key input unit (S50), and when the power switch is turned on Determining whether there is a key input (S60), terminating the operation when there is no key input for a predetermined time (S70), and when there is a key input, closing the solenoid valve and driving the pressurizing unit to increase the air pressure. Step S80, averaging the changed air pressure (S90), detecting the pulse wave transmitted from the human body and storing it in the internal memory (S100), and whether the highest blood pressure is detected But step (S120), and when the highest blood pressure is detected, further pressurizing the predetermined pressure and then stopping the pressurization (S120), and the step of measuring the blood pressure while fine exhaustion after the pressurization is stopped (S130), Detecting the highest blood pressure and the lowest blood pressure (S140), displaying the high pressure / low pressure and the pulse of blood pressure (S150), and terminating the operation while rapidly exhausting by opening the solenoid valve (S160). By the above configuration, the operation of the blood pressure monitor having an optimum pressure control function and its control method according to the embodiment of the present invention are as follows.

When the battery is mounted on the blood pressure monitor by the user, the control program as shown in FIG. 4 stored in the internal memory of the microcontroller 23 is executed by the microcontroller 23, according to an embodiment of the present invention. The operation of the blood pressure monitor having the exhaust control function starts. When the operation starts, the microcontroller 23 opens the solenoid valve 26 by outputting a drive signal to the solenoid valve 26. Next, after initializing the internal memory variable, the microcontroller 23 maintains a low power usage mode in which minimum power consumption is internally performed. In the low power usage mode, the microcontroller 23 determines whether the power switch is turned on by sensing a signal input from the key input unit 21. When the power switch is turned on, the microcontroller 23 determines whether there is a key input from the key input unit 21, and terminates the operation when there is no key input for a predetermined time. However, when there is a key input from the key input section 21, the microcontroller 23 closes the solenoid valve 26 and drives the press section 25 so that the air pressure in the conduit increases. The air pressure generated from the pressurizing portion 25 is transmitted to the air tank 28 made of soft rubber material through the conduit, and the air delivered to the air tank 28 is transmitted to the buffer 29 again. The air stored in the buffer 19 is transferred to the sensor 22, the solenoid valve 26, and the presser 27 through the conduit, and since the solenoid valve 26 is closed, Most of the generated air pressure is transmitted to the pressure bar 27 to allow the pressure bar 27 to tighten the human body (forearm). In this case, the microcontroller 23 uses the sensor 22 to calculate the average of the air pressure which changes in the conduit, detects the pulse wave transmitted from the human body and stores it in the internal memory. 5 to 7 show waveforms in which air pressure generated from the pressing unit 25 and pulse waves transmitted from the human body are synthesized at an initial stage of operation. 5 is a measurement waveform chart of the pressure of the blood pressure monitor when there is no buffer and the tank of the blood pressure monitor having an optimum pressure control function according to an embodiment of the present invention, Figure 6 is the optimum pressure control function according to an embodiment of the present invention Fig. 7 is a waveform diagram of the measurement during pressurization when there is only a tank of the blood pressure monitor, and FIG. 7 is a waveform diagram of the measurement during pressurization when both the tank and the buffer of the blood pressure monitor having the optimum pressure control function according to the embodiment of the present invention. As shown in Figs. 5 to 7 described above, in the embodiment of the present invention, by utilizing the buffering action of the air tank 28 and the buffer 29, the sudden pressure of the air pressure generated from the pressurizing section 25 is used. It can very smoothly mitigate changes (waves). As such, when the abrupt change in air pressure is attenuated, the sensor 22 may detect the pulse wave transmitted from the human body very easily. Next, the microcontroller 23 determines whether the present pressure is the average pressure by comparing the values stored in the internal memory, and if the present pressure is the average pressure, determines whether the highest blood pressure is detected in the pulse wave. . However, if the current pressure is not the average pressure, the above-described processes (S90 to S110) are repeated.

When the highest blood pressure is detected from the pulse wave signal included in the air pressure signal, the microcontroller 23 stops the pressurization by outputting a driving stop signal to the pressurizing section 25 after a predetermined time.

Therefore, the blood pressure can be comfortably measured by detecting the highest blood pressure value differently depending on the physical state and the blood pressure state of the subject, and stopping the driving of the pressing unit 25 at the most appropriate time.

After the pressurization is stopped, the human body portion tightened by the pressing table 27 is in a state where the blood pressure is elevated, and in this state, the microcontroller 23 measures the blood pressure while finely discharging air. The high and low pressures of the blood pressure measured in this way are displayed on the outside through the display unit 24. After the measurement of the blood pressure is finished, the microcontroller 23 rapidly exhausts by opening the solenoid valve 26, and then ends the operation.

As described above, in the embodiment of the present invention, after extracting and analyzing the arterial pressure of the subject, the blood pressure is measured by stopping the driving of the pressure means at the pressure capable of measuring blood pressure, thereby having the effect of providing comfort to the subject. A blood pressure monitor having an optimum pressure control function and a control method thereof can be provided. This effect of the present invention can be used in the fields of designing, manufacturing, and selling blood pressure monitors.

Claims (4)

A user inputs a key input unit for inputting a command, a sensor for detecting air pressure and pulse wave of a conduit, and converts it into an electrical signal and outputs the blood pressure using a signal input from the sensor, and then displays it externally. A microcontroller for outputting an information signal for controlling, a pressurizing unit driven according to a control signal from the microcontroller to pressurize the air pressure in the conduit, an air tank for temporarily storing the air pressure transmitted from the pressurizing unit, and a control from the microcontroller A solenoid valve that exhausts air in the conduit to the outside by being turned on and off according to a signal, a compression table for transmitting pulse waves generated from a human body to the sensor, and a display unit for externally displaying blood pressure according to an information signal input from the microcontroller. A conduit to the air tank It is connected, the blood pressure monitor having the optimum pressure control comprising a buffer for transmitting the air tank by a second time buffer. The blood pressure monitor having an optimum pressure control function according to claim 1, wherein the air tank is made of a soft rubber material. The blood pressure monitor according to claim 1 or 2, wherein the air tank and the buffer buffer the air pressure so as to linearly change the air pressure. When the battery is installed, the operation starts by opening the solenoid valve, initializing the internal memory variable, maintaining the low power usage mode, determining whether the power switch is turned on from the key input unit, and turning on the power switch. If there is no key input for a predetermined time, the operation is terminated, and if there is a key input, the air pressure is increased by closing the solenoid valve and driving the pressurizing unit, and changing the air pressure. Averaging, detecting and storing the pulse wave transmitted from the human body in the internal memory, determining whether the highest blood pressure is detected, and further stopping the pressurization after pressurizing a predetermined pressure when the highest blood pressure is detected; After this stops, the blood pressure is measured while bleeding fine and the highest and lowest blood pressure. Detection and control method for a blood pressure monitor having the optimum pressure control, characterized in that comprising the step of displaying a high-pressure / low-pressure and pulse rate and blood pressure, terminating the operation, while the rapid exhaust by opening the solenoid valve.