KR101016220B1 - Measuring Apparatus of Blood Pressure - Google Patents

Abstract

The present invention provides a measurement unit for wirelessly measuring the blood pressure at regular intervals; And a storage unit which is separated from the measuring unit and wirelessly receives and records the blood pressure measured by the measuring unit. In addition, as another category of the present invention, the first step of changing the capacitance in accordance with the blood pressure in each pressure sensor; A second step of the transmission unit transmitting a resonant frequency to the outside through the RFID module based on the capacitance; A third step of receiving and detecting a resonant frequency by the frequency detector of the storage unit; A fourth step of calculating a pressure based on the detected resonance frequency of the pressure converting unit of the storage unit; And a fifth step of storing the pressure in the memory device of the storage unit. The blood pressure measuring method using the pressure sensor may include a pressure sensor having a simple configuration without a microprocessor. Reduced production cost, can be operated at low power, can be miniaturized, and the structure is simple, so the failure rate of the parts is low, thereby improving the durability. In addition, it is possible to wirelessly transmit by integrating with the RFID module to continuously measure the blood pressure, it is possible to store the measured blood pressure by time.

Blood pressure, pressure, measurement, sensor

Description

Blood pressure measuring device {Measuring Apparatus of Blood Pressure}

The present invention relates to a blood pressure measuring device, and more particularly, to a blood pressure measuring device capable of storing a wide range of blood pressure measured by using an RFID module for 24 hours and storing the measured blood pressure in a memory device.

In general, blood pressure refers to the pressure exerted on the side walls of arteries when the heart pumps blood. This blood pressure is determined by one-time cardiac output and peripheral vascular resistance. Here, the cardiac output is determined by the strength and weakness of the contractile force of the heart, the peripheral resistance is determined by the resistance caused by the contraction of the arterioles. However, daily blood pressure refers to arterial pressure, which is usually measured for 5 minutes, and then refers to the casual blood pressure (Casual Clinic Blood Pressure) measured on the forearm.

These blood pressures change under various conditions. Among them, the influence of position, measurement site, temperature, physical activity, alcohol or stress has a big influence on the change of blood pressure. Assuming that these conditions are the same, even if you pay close attention to the measurement, there are many differences due to the inherent Circadian Variation, which sometimes results in a difference of 10 mmHg to 30 mmHg.

To reduce the errors caused by fluctuations in blood pressure, it is good to measure blood pressure frequently. In order to measure the blood pressure from time to time, a portable blood pressure measuring device capable of measuring blood pressure directly by a user for 24 hours is spreading.

However, since the conventional portable blood pressure meter is manufactured based on a microprocessor, a large amount of power is used using more than 10,000 transistors, and the structure is complicated, so that miniaturization is difficult and manufacturing cost is high. In addition, due to the complex structure, there are many failures of the measuring device and weak durability.

Accordingly, an object of the present invention is to provide a blood pressure measuring device that stores blood pressure measured by measuring blood pressure from time to time using an RFID module.

An object of the present invention as described above is a measurement unit for wirelessly measuring the blood pressure at regular intervals; And a storage unit which is separated from the measuring unit and wirelessly receives and records the blood pressure measured by the measuring unit.

In addition, as another category of the present invention, the first step of changing the capacitance in accordance with the blood pressure in each pressure sensor; A second step of the transmission unit transmitting a resonant frequency to the outside through the RFID module based on the capacitance; A third step of receiving and detecting a resonant frequency by the frequency detector of the storage unit; A fourth step of calculating a pressure based on the detected resonance frequency of the pressure converting unit of the storage unit; And a fifth step of storing the pressure in the memory device of the storage unit. The method may be achieved by a blood pressure measurement method using a pressure sensor.

According to the present invention, a single transistor can be implemented without a microprocessor, and thus, a pressure sensor having a simple configuration can reduce production costs, operate at low power, can be miniaturized, and have a simple structure. Therefore, the failure rate of the component is low, thereby improving the durability. In addition, it is possible to wirelessly transmit by integrating with the RFID module to continuously measure the blood pressure, it is possible to store the measured blood pressure by time. It also measures blood pressure over a wide range, so you can see the pulse distribution of your veins. The blood pressure stored in this way is effective in identifying the doctor or oriental medical doctor.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

<Configuration of blood pressure measuring device>

1 is a perspective view of a blood pressure measuring apparatus according to the present invention. As shown in FIG. 1, the blood pressure measuring device 100 is worn on a wrist, and is measured by the measuring unit 1000, which is easy to carry, such as a measuring unit 1000 and a waistband to measure blood pressure at regular intervals, and records the blood pressure measured by the measuring unit 1000. It consists of a storage unit 2000.

The measuring unit 1000 according to the present invention includes an attachment part 1100 having a band, tape, or clock shape, and a plurality of blood pressure measuring units 1200 attached thereto. Here, the blood pressure measuring unit 1200 is a plurality of pressure sensors 1210 having a matrix structure, a transmitter for converting the capacitance (C ₁ ) measured by the pressure sensor 1210 to the resonant frequency (f ₁ ) to transmit to the outside And a power supply unit 1230 for applying power to the transmission unit 1220.

Figure 2 shows a side view of the pressure sensor according to the present invention. As shown in FIG. 2, the pressure sensor 1210 according to the present invention includes a first insulating part provided between the first electrode layer 1211 to the third electrode layer 1215 and each of the electrode layers 1211, 1213, and 1215. 1212 and the second insulating portion 1214. Here, the first electrode layer 1211 to the third electrode layer 1215 may be made of a thin film conductor or semiconductor such as silicon, stainless steel, or germanium. As the first insulating portion 1212 and the second insulating portion 1214 according to the present invention, it is preferable to use an elastic insulator such as a dielectric or a vacuum insulating plate.

The pressure sensor 1210 having the above-described configuration may further include an inductor 1216 on one side of the first electrode layer 1211 and the third electrode layer 1215, and the first electrode layer 1211 to the third electrode layer 1215. And one side of the inductor 1216 is further provided with a circuit connection terminal 1217 for circuit connection. At this time, the circuit configuration of Colpitts type and Hartley type is possible depending on the use of the circuit connection terminal 1217, and the use capacity is also three configurations, C ₁ , C ₂ or C ₁ // C ₂ . This is possible. At this time, C ₂ serves to facilitate the initial adjustment of the resonant frequency (f ₁ ).

The pressure sensor 1210 may be attached to the attachment part 1100 according to wearing conditions such as n × n matrix structure consisting of 5 × 5 to 10 × 10 structures or n × m matrix structures such as 5 × 10. It can vary.

Transmitter 1220 according to the present invention is provided on one side of the attachment portion 1100 is connected to a plurality of pressure sensors 1210 to measure the capacitance C ₁ measured by the pressure sensor 1210 resonant frequency (f ₁₎ ) To be converted and sent to the outside. The transmitter 1220 may use an RFID module.

The power supply unit 1230 according to the present invention is provided to be connected to the transmission unit 1220 on one side of the attachment unit 1100 and is for applying power to the transmission unit 1220, and it is preferable to use a small battery such as a watch battery.

The storage unit 2000 according to the present invention includes a frequency detector 2100 for detecting a resonance frequency f ₁ transmitted from the transmitter 1220 of the measurement unit 1000, and a pressure P for the detected resonance frequency f ₁ . And a memory device 2300 for storing the pressure P output from the pressure converter 2200 and the pressure converter 2200. Here, the frequency detector 2100 is a device for detecting the resonant frequency (f ₁ ) transmitted from the transmitter 1220, the resonant frequency (f ₁ ) detection method operates on the same principle as a variable condenser (Variable Condenser). The pressure converter 2200 is a device for converting the resonance frequency f ₁ detected by the frequency detector 2100 into a pressure P, and it is preferable to use a pressure converter that can achieve this purpose. The memory device 2300 is a device for storing the pressure P converted by the pressure converter 2200 for each pressure sensor 1210 and time, and it is preferable to use a memory device capable of accomplishing this purpose.

Figure 3 shows a circuit diagram of the blood pressure measuring apparatus according to the present invention. As shown in FIG. 3, when power is applied to the circuit from the power supply unit 1230, the pressure sensor 1210 oscillates, the signal is copied through the antenna of the RFID module which is the transmitter 1220, and the resonance frequency f ₁ is increased. Send. The resonance frequency f ₁ transmitted in this way is received by the radio frequency detector from the storage unit 2000 provided outside the blood pressure measuring apparatus 100 to measure the pressure P.

In the blood pressure measuring device 100 having such a configuration, the first electrode layer 1211 of the pressure sensor 1210 is deformed by the wearer's blood pressure, and thus the electrical pressure between the first electrode layer 1211 and the second electrode layer 1212 is changed. The capacity C ₁ changes. At this time, each pressure sensor 1210 measures each blood pressure in a wide range. The resonance frequency f ₁ is changed by Equation 1 due to the change in the capacitance C ₁ .

The changed resonant frequency f ₁ is amplified by the transistor and transmitted to the outside by the RFID module of the transmitter 1220. The resonant frequency f ₁ transmitted from the transmitter 1220 is detected by the frequency detector 2100 included in the storage 2000, and is converted into a pressure P by the pressure converter 2200. The pressure P measured by the pressure converter 2200 is stored in each pressure sensor 1100 and a memory device 2300 such as a flash memory for each time.

This blood pressure measurement is to measure the blood pressure for a certain period of time at regular intervals. For example, the pulse rate is measured at 10 minute intervals for 1 minute or at 20 minute intervals for 1 minute. This cycle and measurement time can be adjusted according to the user's health condition.

<Method of measuring blood pressure>

4 is a flowchart illustrating a blood pressure measuring method according to the present invention. As shown in FIG. 4, first, the first electrode layer 1211 of each pressure sensor 1210 having a matrix structure is deformed by the wearer's blood pressure, thereby deforming the first electrode layer 1211 and the second electrode layer ( The capacitance C ₁ between 1213 is changed (S100).

Next, the resonance frequency f ₁ is calculated based on the changed capacitance C ₁ based on Equation 1 above, and the resonance frequency f ₁ is transmitted to the outside through the RFID module of the transmitter 1220. (S200).

Next, the frequency detector 2100 of the storage unit 2000 receives and detects the resonance frequency f ₁ (S300).

Next, the pressure converter 2200 of the storage unit 2000 calculates the pressure P based on the resonance frequency f ₁ detected by the frequency detector 2100 to measure the blood pressure (S400).

Finally, the blood pressure measured by the pressure converter 2200 is stored in the memory device 2300 according to time for each pressure sensor 1210. The stored blood pressure data is used as regular checkup data by a doctor or a doctor. To this end, the storage unit 2000 is provided with a USB port (not shown).

As described above, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. It is therefore to be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention, and therefore, the present invention is limited only to the matters described in the drawings. It should not be interpreted.

1 is a perspective view of a blood pressure measuring apparatus according to the present invention,

2 is a side view of the pressure sensor according to the present invention;

3 is a circuit diagram of a blood pressure measuring device according to the present invention;

4 is a flowchart illustrating a blood pressure measuring method.

<Explanation of symbols for the main parts of the drawings>

100: blood pressure measuring device 1000: measuring unit

1100: attachment portion 1200: blood pressure measurement unit

1210 pressure sensor 1211 first electrode layer

1212: first insulating portion 1213: second electrode layer

1214: second insulation 1212: third electrode layer

1216: inductor 1217: circuit connection terminal

1220: transmitter 1230: power unit

2000: storage 2100: frequency detector

2200: pressure converter 2300: memory device

C ₁ : Capacitance between the first electrode layer and the second electrode layer

C ₂ : Capacitance between the second electrode layer and the third electrode layer

f ₁ : resonant frequency

P: pressure

Claims (13)

Measuring unit 1000 for measuring and transmitting the blood pressure at regular intervals; And A storage unit 2000 separated from the measurement unit 1000 and wirelessly receiving and recording the blood pressure measured by the measurement unit 1000; The measuring unit 1000 is made of a band, tape or watch attached to the wrist attached to the attachment portion 1100 and a plurality of blood pressure measurement unit 1200 is coupled to the attachment portion 1100 to measure the blood pressure, The blood pressure measuring unit 1200 The first electrode layer 1211, the first insulating portion 1212 provided under the first electrode layer 1211, the second electrode layer 1213 provided under the first insulating portion 1212, and the second electrode layer ( 1213) a second insulating part 1214 provided at a lower end, and a third electrode layer 1215 and a first electrode layer 1211 and a third electrode layer 1215 provided at a lower end of the second insulating part 1214. A pressure sensor 1210 formed of an inductor 1216; A transmitter 1220 for converting the capacitance C ₁ measured by the pressure sensor 1210 into a resonant frequency f ₁ and transmitting the result to the outside; And A power supply unit 1230 for supplying power to the transmitter 1220; The storage unit 2000 A frequency detector 2100 for detecting a resonance frequency f ₁ transmitted from the blood pressure measuring unit 1000, A pressure converter 2200 for converting the resonance frequency f ₁ detected by the frequency detector 2100 into a pressure P; Blood pressure measuring device, characterized in that consisting of a memory device (2300) for storing the pressure (P) measured by the pressure conversion unit (2200). delete delete The method of claim 1, The first insulating part 1212 and the second insulating part 1214 are blood pressure measuring apparatus, characterized in that the elastic insulator. The method of claim 4, wherein The elastic insulator is a blood pressure measuring device, characterized in that the dielectric or vacuum insulating plate. The method of claim 1, The transmitter 1220 is a blood pressure measuring device, characterized in that the RFID module. The method of claim 1, The power supply unit 1230 is a blood pressure measuring device, characterized in that the battery or piezoelectric generator. The method of claim 1, The pressure sensor 1210 is a blood pressure measuring device, characterized in that consisting of a matrix structure. The method of claim 8, The matrix structure is a blood pressure measuring device, characterized in that consisting of n × n or n × m matrix structure. The method of claim 9, The n and m are blood pressure measuring device, characterized in that the natural number 2 to 20. delete delete delete

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