KR200361681Y1 - Sphygmomanometer with three-dimensional positioning function - Google Patents

Abstract

The present invention discloses a blood pressure monitor having a 3D positioning function, which includes a pressure sensor, an alarm unit, a memory unit, a 3D acceleration sensor chip, a display device, a driving device, and a microprocessor chip connected to an air valve, respectively. When the blood pressure of a person is measured, the 3D acceleration sensor chip detects the spatial position of the measurement cuff of the blood pressure monitor and sends parameters related to the detected spatial position to the microprocessor chip. At this time, the microprocessor chip will retrieve a predetermined range of parameters related to the spatial position from the storage unit and compare this range with the values of the detected parameters. If the values of the detected parameters exceed a certain range of parameters, the microprocessor chip will generate an alarm through the alarm unit until the spatial position is correct. Therefore, the person who performs blood pressure measurement can always obtain the most accurate measurement.

Description

Blood pressure monitor having three-dimensional positioning function {SPHYGMOMANOMETER WITH THREE-DIMENSIONAL POSITIONING FUNCTION}

The present invention relates to a blood pressure monitor having a three-dimensional (3D) positioning function, more specifically, to detect the spatial position of the measurement cuff of the blood pressure monitor, and send the parameters of the detected spatial position to the chip processor, the comparison of the parameters Thereafter, the present invention relates to a blood pressure monitor using a 3D acceleration sensor chip that enables the tester to move the posture of the measurement cuff of the blood pressure monitor or a related part of the tester body to the correct spatial position.

In general, blood pressure monitors are divided into conventional mercury type and electronic type, which not only waste time, but also require professionally trained and skilled people to measure blood pressure accurately. Electronic blood pressure monitors, on the other hand, are also divided into desktop, wrist, tunnel, and finger types. The electronic blood pressure monitor does not need to be calibrated in advance, and since the measurement result is displayed on the display device, its use is simple and convenient for the user. Although electronic sphygmomanometers have the above convenience, it is understood that the results of blood pressure measurement depend not only on the time of making the measurement, but also on the spatial position of the wrist or the relevant part of the body to be measured. For example, the morning blood pressure is generally lower than the afternoon blood pressure, and the correct position for placing the measurement cuff of the wrist sphygmomanometer to measure blood pressure should be level with the heart. In general, people cannot determine if the measurement cuff of the wrist sphygmomanometer has been raised to the correct spatial position, and the wrist sphygmomanometer does not provide a three-dimensional positioning function, but merely moves the blood pressure monitor in different directions such as up, down, left and right. Is based on his own experience. This often leads to inaccurate blood pressure measurements.

1 is a perspective view of a blood pressure monitor of the present invention.

2 is a schematic circuit diagram of a blood pressure monitor according to a preferred embodiment of the present invention.

3 is a schematic circuit diagram of a blood pressure monitor according to a preferred embodiment of the present invention.

4 is a configuration diagram of the X-axis and Y-axis of the piezoelectric transformer and the bridge sensor of the 3D acceleration sensor chip of the present invention.

4A is a configuration diagram of the Z axis of the piezoelectric transformer and the bridge sensor of the 3D acceleration sensor chip of the present invention.

Figure 5 shows the movement when the tester uses a wrist sphygmomanometer to measure blood pressure according to the present invention.

5A illustrates the movement along the X and Y axes when the tester uses a wrist sphygmomanometer to measure blood pressure in accordance with the present invention.

5B illustrates movement along the Z axis when a user uses a wrist sphygmomanometer to measure blood pressure in accordance with the present invention.

Explanation of symbols on the main parts of the drawings

21: amplifier 22: power supply control unit

23: bridge sensor 24: analog / digital conversion unit

25 microprocessor chip 26 display unit

27: input unit 28: alarm unit

29: memory unit 30: drive device

40: air valve 50: 3D acceleration sensor chip

In view of the shortcomings of the prior art, the inventors of the present invention have focused on the point of the present problem, and have begun to study improvements to overcome the shortcomings and pursue possible solutions. After extensive research, analysis and design, the inventors devised a blood pressure monitor with three-dimensional (3D) positioning.

The main object of the present invention is to provide a blood pressure monitor having a 3D positioning function, the blood pressure monitor having a microprocessor chip, which is connected to a memory unit and a 3D acceleration sensor chip, respectively. When the blood pressure monitor according to the present invention is used, the 3D acceleration sensor chip detects the spatial position of the measurement cuff of the blood pressure monitor and then sends the parameters of the spatial position to the microprocessor chip. At this time, the microprocessor chip will retrieve a predetermined range of related parameters from the storage unit for comparison with the parameters for the detected spatial position. If the values of the detected parameters exceed a certain range of related parameters, then the position of the measurement cuff of the blood pressure monitor or the relevant part of the examiner's body is incorrect. The microprocessor chip will generate an alarm through the alarm unit to alert the tester to move the measurement cuff of the blood pressure monitor to a position until the values of the parameters for the spatial position are within a predetermined range, and then the alarm unit Will stop the alarm message. In other words, the position of the measurement cuff of the sphygmomanometer or of the relevant part of the examiner's body is placed in the correct position. Therefore, the blood pressure measurement made by the user will be more accurate.

Another object of the present invention is to provide a blood pressure monitor having a 3D positioning function, the control unit of which is connected to a display device, when the blood pressure monitor is used, the display device can display the results of the blood pressure measurement of the tester.

Another object of the present invention is to provide a blood pressure monitor having a 3D positioning function, wherein the 3D acceleration sensor chip is a semiconductor chip composed of a piezoelectric transformer (PZT), a bridge type sensor, and a corresponding electronic device, and is located on the piezoelectric transformer. The plumb bob, and the seating extending from the X, Y, and Z axes of the shaft tail will shake as the spatial position changes. The seating is connected to the bridge-type sensor so that the seating moves according to the measurement cuff carried by the tester, and if the seating is inclined at different angles, the piezoelectric transformer will generate a voltage change. The bridged sensor will send this change to the microprocessor chip, converting it into a spatial position related parameter. The microprocessor chip will retrieve a range of values for the spatial position related parameters from the storage unit and compare these values with the values of the detected spatial position parameters. If the detected value of the relevant parameters exceeds the range of values of the related parameters, the spatial position of the measuring cuff of the blood pressure monitor or the position of the relevant part of the tester body is not correct, and until the values of the measured parameters are within a predetermined range of related parameters, The examiner will be advised to move the measurement cuff to the correct position or to adjust the posture of the relevant part of the user's body.

In order for the examiner to more easily understand the purpose, structure, innovative characteristics, and performance of the present invention, the preferred embodiment is used in conjunction with the accompanying drawings for detailed description of the present invention.

Reference is made to FIGS. 1, 2 and 3 for a sphygmomanometer with a 3D positioning function, the present invention using a wrist sphygmomanometer, for example. The sphygmomanometer includes an airbag cuff 10, an attachment tape 11 attached on both ends of the airbag cuff 10, a housing 20 positioned on the airbag cuff, and the housing 20. It has a pressure sensor 21 located in. The pressure difference is used to detect changes in blood pressure. The pressure sensor 21 includes an amplifier 211 and a bridge sensor 23, the input terminal of the amplifier 211 is connected to the power supply unit 22 and the resistor 212, the output terminal of the amplifier 211 Connected to the bridge sensor 23, the result detected by the pressure sensor 21 is amplified by the amplifier 211, and the voltage is output by the bridge sensor 23.

The bridged sensor 23 is also connected to an analog / digital conversion unit 24 having a plurality of amplifiers 241, resistors 242, and capacitors 243. Since the circuit of these electronic devices is the same as a general analog / digital conversion circuit, the structure thereof is not described here. The analog / digital conversion unit 24 converts the input analog signal into a digital signal.

In addition, the analog / digital conversion unit 24 is connected to a microprocessor chip 25, and the microprocessor chip according to the present preferred embodiment is a multitasking microprocessor chip (MCU). The microprocessor chip 25 is connected to the power supply unit 22, and the microprocessor chip 25 is connected to the display unit 26, the input unit 27, the alarm unit 28, and the storage unit 29. The display unit 26 may be a liquid crystal display (LCD) module for displaying a result of the blood pressure measurement of the user. In addition, the input unit 27 may be a switch module provided with more than one connected switches 271, each of which is connected to a resistor 272. In addition, the alarm unit 28 is used to generate a warning sound, and the storage unit 29 may be a memory for storing data.

See FIGS. 1, 2 and 3. The microprocessor chip 25 is connected to the drive device 30 and the air valve 40, respectively. The drive device 30 and the air valve 40 are connected to the microprocessor chip 25 via transistors 31 and 41, and the drive device 30 and the air valve 40 are connected to the airbag cuff 10. . In addition, the driving device 30 according to the present embodiment is a motor, and when the airbag cuff 10 is wound around the user's wrist, the microprocessor chip 25 starts to drive the driving device 30 to the airbag cuff 10. Filling the air, the airbag cuff 10 swells to compress the blood vessels of the wrist. The drive device 30 will stop when the required pressure is achieved. Thus, cardiac contraction pressure (high pressure) and cardiac diastolic pressure (low pressure) are measured. At this time, the microprocessor chip 25 turns on the air valve 40 to release the air in the airbag cuff 10 to facilitate detection of values of cardiac contraction pressure (high pressure) and cardiac expansion pressure (low pressure).

See FIGS. 2, 3, 4, 4A, and 5. The microprocessor chip 25 is connected to the 3D acceleration sensor chip 50, which has a semiconductor chip composed of a piezoelectric transformer 51, a bridge type sensor 52, and a corresponding electronic device. The piezoelectric transformer 51 has a shaft tail 511 thereon, the shaft tail having a seating 512 that vibrates in accordance with a change in spatial position, and the seating 512 is connected to the bridge-type sensor 52. The seating 512 moves as the user's arm moves. If the user's arm is inclined at different angles, the piezoelectric transformer 51 will generate a voltage change. The value of the parameter for the voltage change is sent to the microprocessor chip 25 via the bridged sensor 52 and converted into a parameter for the spatial position. The microprocessor chip 25 will retrieve the predetermined values of the spatial position related parameters from the storage unit 29 and compare them with the detected values of the parameters. If the values of the detected parameters exceed a range of values, the spatial position of the measurement cuff wound around the wrist or the position of the posture of the relevant part of the examiner's body is not correct so that the alarm unit 28 determines that the tester corrects the measurement cuff. Either by moving to a spatial position or by changing the posture of the user's body to the correct spatial position, a sound will be generated until the values of the detected parameters are within a range of values. Thereafter, the alarm unit 28 stops, and the user knows that the associated portion of the wrist or the examiner's body has been moved to the correct position.

See FIGS. 2, 3, 5, 5A and 5B. When the sphygmomanometer is used, the attachment member 11 attaches the airbag cuff to the wrist of the user, after the power unit 22 is turned on, the wrist with the sphygmomanometer is started to move upward toward the position of the heart, and the housing 20 The 3D acceleration sensor chip 50 in the body moves as the wrist moves, and sends the obtained value to the microprocessor chip 25, so that the microprocessor chip 25 and the original standard data stored in the memory unit 29 are stored. The obtained data will be compared. If the values of the retrieved parameters are out of range, the microprocessor chip 25 will instruct the alarm unit 28 to notify the tester to generate a sound to suggest that the tester move the wrist. The 3D acceleration sensor chip 50 moves in accordance with the movement of the wrist, sending the detected parameters to the microprocessor chip 25 continuously, where the microprocessor chip 25 has the values of the detected parameters as the original stored parameters. Comparisons will be made until they are within a predetermined range. The alarm unit 28 will then stop or generate a different sound to inform the tester that the wrist has been moved to the correct position. At this time, the microprocessor chip 25 turns on the driving device 30 to pump air to the airbag cuff 10, and the airbag cuff 10 is inflated to press the blood vessels of the wrist. As soon as the required pressure is achieved, the drive device 30 stops and then drives the pressure sensor 11 to perform the measurement. At this time, the microprocessor chip 25 starts, and the air valve 40 releases the air in the airbag cuff 10 until the cardiac contraction pressure (high pressure) and the cardiac diastolic pressure (low pressure) are measured. The measurement result is displayed on the display unit 26 and will be stored in the storage unit 29.

In summary, the present invention is novel in shape, structure and apparatus, and the present invention uses a 3D acceleration sensor chip 5 for positioning, so the present invention is desktop, wrist, tunnel and finger. Applicable for different electronic blood pressure monitors, including the like. Therefore, the present invention is more accurate and convenient than the prior art. Here, the present invention improves performance over the conventional configuration, and satisfies the requirements of the patent application, and is clearly an excellent idea for this kind of product.

Although the present invention has been described by way of examples and as preferred embodiments, it is to be understood that the present invention is not limited thereto. On the contrary, it is intended to cover various modifications and similar arrangements and processes, and the scope of the appended claims should therefore be given in the broadest interpretation so as to encompass all such modifications and similar arrangements and procedures.

Claims (6)

In a blood pressure monitor having a 3D positioning function, A pressure sensor having an amplifier and a bridge sensor for detecting a change in blood pressure and for amplifying and adjusting a voltage; An analog / digital conversion unit connected to the pressure sensor and capable of converting an electrical signal of the pressure sensor into a digital signal; A microprocessor chip connected to the analog / digital conversion unit for determining processing; A display unit connected to the microprocessor chip for displaying a result of blood pressure measurement; An input unit connected to the microprocessor chip for inputting related settings; A storage unit connected to the microprocessor chip for storing setup data and blood pressure measurements; A drive device connected to the microprocessor chip for pumping air; An air valve connected to the microprocessor chip for releasing air; Connected to the microprocessor chip to generate a voltage that is shifted, the value of the voltage is converted into a digital parameter so that the digital parameter is sent to the microprocessor chip so that the tester can correct the A 3D acceleration sensor chip capable of determining position; And A power unit connected to the pressure sensor, the microprocessor chip, the display unit, and the input unit to supply power; As the components, when the sphygmomanometer is in use, the acceleration sensor chip detects the position of the sphygmomanometer and sends the parameters for the detected spatial position to the microprocessor chip, while the microprocessor chip is configured to store the memory unit. Retrieve the predetermined value for the related parameters from and compare it with the parameters for the detected spatial position, and if the detected parameters exceed a predetermined range of the related parameters, the measurement cuff is not correct spatially. When positioned and the detected parameters fall within a predetermined range of the relevant parameters, the correct spatial position is achieved, and the microprocessor chip controls the pressure sensor, the drive device, and the air valve to To perform measurements Blood Pressure Monitor with 3D positioning features of Jing. The sphygmomanometer having a 3D positioning function according to claim 1, wherein the input unit is a switch module. The blood pressure monitor having a 3D positioning function according to claim 1, wherein the display unit is a liquid crystal display module. The sphygmomanometer having a 3D positioning function according to claim 1, wherein said storage unit is a memory. The sphygmomanometer of claim 1, wherein the microprocessor chip is connected to an alarm unit for selectively generating an alarm and a warning sound. The sphygmomanometer having a 3D positioning function according to claim 1, wherein the driving device is a motor.