KR101963790B1 - glucose measuring device for automatically percepting a code signal of senser strip - Google Patents

Abstract

The present invention provides a sensor chip comprising: a sensor strip having a carbon electrode having a plurality of code combination values selectively printed on an electrode port and shipped; When the sensor strip is inserted, various cord combination values of the sensor strip corresponding to the shape of the carbon electrode printed on the electrode port of the sensor strip are automatically read to correct the sensed measurement deviation of the sensor strip, A blood glucose measurement device for automatically recognizing a code signal of a sensor strip including a blood glucose measurement device main body.
In order to recognize a code value of a sensor strip, a carbon electrode having a plurality of code combination values is selectively printed and shipped to an electrode port of a sensor strip without having an external circuit separately from the blood glucose meter, Since the measuring device is a system that reads and processes easily, an expensive code recognition circuit is not used, and thus the manufacturing cost of the blood glucose measuring device is significantly reduced.

Description

    TECHNICAL FIELD [0001] The present invention relates to a glucose measuring device for automatically recognizing a code signal of a sensor strip,

The present invention relates to a blood glucose measurement device for automatically recognizing a code signal of a sensor strip. In particular, in order to recognize a code value of a sensor strip, it is not necessary to provide an external circuit separately in the blood glucose measurement device, The present invention relates to a blood glucose measurement device for automatically recognizing a code signal of a sensor strip that significantly reduces the manufacturing cost of the blood glucose measurement device since it is a structure in which a carbon electrode having a combination value is selectively printed and shipped and the blood glucose measurement device reads and processes the same .

Generally, a blood glucose measuring apparatus is a blood glucose measuring apparatus in which a test strip, that is, a sensor strip (biosensor strip) is inserted into a charging port of a blood glucose measurement device, and a small amount of blood collected at the fingertip is collected into a sensor strip Is automatically sucked into the sensor strip inlet, and the result is displayed on the screen of the blood glucose meter. Such a sensor strip is used for quantitatively or qualitatively analyzing a specimen collected from a human body. The sensor strip is coated on an insulator having a certain size to electrically conduct electricity to cause an electrochemical reaction with the specimen, And an electrode formed by pasting. However, since the sensor strip has a sensing measurement deviation due to the characteristics of the sensor strip manufacturing process, the sensor strip has slightly different characteristics at each manufacturing time. Therefore, in order to compensate the sensing measurement deviation on the characteristics of the sensor strip manufacturing process, a unique code that can represent the sensing measurement deviation is given to each sensor strip production, and the code of the sensor strip is recognized And compensates the sensing measurement deviation according to the inherent code, thereby outputting a more accurate result.

      As a method of recognizing a sensor strip, there is a method of using a code chip and a method of manually inputting a code into a blood sugar measuring device.

As a prior art related to the blood glucose measurement device using the conventional sensor strip as described above, Korean Patent Laid-Open Publication No. 10-2008-0064705 (entitled " BioStrip Management System ") filed by Health & Life Company Limited, Method; public date: 07-Jul-09) is known.

     1, a strip connector 71 for inserting and fixing a biosensor 70 (hereinafter referred to as a sensor strip) for blood glucose measurement, as shown in FIG. 1;

      An analog switch 73 for supplying a voltage signal set by the voltage source portion 72 to the sensor strip 70 inserted into the strip connector 71;

      An operational amplifier 74 for amplifying and outputting an analog blood glucose measurement current measured by the sensor strip 70 at a predetermined level;

      The blood glucose measurement current output from the OP amplifier 74 is analyzed and the current blood glucose measurement value is calculated and displayed on the display 75 and the code signal of the sensor strip 70 input through the key input unit 76 And then supplies the operating voltage of the sensor strip 70 through the voltage source unit 72.

      The MCU 76 is connected to a memory unit 78 for storing information operated by the blood glucose meter 77.

     Meanwhile, in the operation of the conventional blood glucose measurement device for recognizing the code of the conventional sensor strip, the sensor strip 70 is inserted and fixed in the strip connector 71 for measurement by the measurement person. When the user manually inputs the code signal of the sensor strip 70 through the key input unit 76 of the blood glucose measurement device 77, the MCU 76 of the blood glucose measurement device 77 transmits the code signal of the sensor strip 70 70 to recognize the operating voltage of the corresponding sensor strip 70 stored in the memory unit 78 and generate the operating voltage of the corresponding sensor strip 70 through the voltage source unit 72, 73). Then, the analog switch 73 supplies a voltage signal set to the sensor strip 70 inserted in the strip connector 71, so that normal measurement is performed.

      In this process, the sensor strip 70 measures blood glucose through blood sampling by the measurer, and amplifies the measured blood glucose measurement current of the analog to a certain level through the OP amplifier 74, and inputs the amplified current to the MCU 76. Then, the MCU 76 analyzes the blood glucose measurement current output from the OP amplifier 74 and compensates the sensing measurement deviation according to the code of the sensor strip 70, calculates the current blood glucose measurement value, ), So that the measurer can confirm his / her current blood glucose level.

      In addition, the blood glucose measurement device for recognizing the code of the sensor strip as described above includes an optical processing method in which a specific color is printed on the back side of the sensor strip and is read and processed through an optical sensor. A device for recognizing a code of a sensor strip by using a memory chip having a lot characteristic information of a sensor strip separately is provided.

However, in order to recognize the code value of the sensor strip, the blood glucose measurement device for recognizing the code of the conventional sensor strip as described above may separately attach an external circuit such as a memory chip having lot characteristics information of the sensor strip to the blood glucose measurement device Or a recognition process module capable of recognizing the code of the sensor strip is installed. Therefore, the manufacturing cost of the blood glucose measurement device is significantly increased, and in order to recognize the code value of the sensor strip, An external circuit for separately recognizing the code value of the sensor strip is required to be complexly designed and implemented. Therefore, there is a problem in that the board design of the blood glucose measurement device is significantly degraded.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in order to solve the above-mentioned problems of the prior art, and it is an object of the present invention to provide a method and apparatus for selecting and printing a carbon electrode having a plurality of code combinations on an electrode port of a sensor strip, And it is an object of the present invention to provide a blood glucose measurement device for automatically recognizing a code signal of a sensor strip which does not need to use an expensive code recognition circuit separately, and a control method thereof.

It is a further object of the present invention to provide a blood glucose measurement device that does not require complicated designing of an external circuit for recognizing a code value of a sensor strip, The present invention provides a blood glucose measurement device and a control method thereof that can automatically perform a board design and thereby automatically recognize a code signal of a sensor strip that significantly improves the board design of the blood glucose measurement device.

According to an aspect of the present invention, there is provided a carbon nanotube sensor comprising: a sensor strip having a carbon electrode having a plurality of code combination values selectively printed on an electrode port;

When the sensor strip is inserted, various cord combination values of the sensor strip corresponding to the shape of the carbon electrode printed on the electrode port of the sensor strip are automatically read to correct the sensing measurement deviation of the sensor strip, A blood glucose measurement device for automatically recognizing a code signal of a sensor strip including a blood glucose measurement device main body.

According to the present invention, when a sensor strip is manufactured, a plurality of carbon electrodes having a code combination value are selected and printed on an electrode port of a sensor strip, and various combinations of code values realized by the carbon electrodes are mounted The code combination value of the sensor strip is automatically read and processed by the blood glucose measurement device so that the code value of the sensor strip can be recognized without requiring an external circuit separately in the blood glucose measurement device, The value is easily read and processed. Therefore, an expensive code recognition circuit is not used, and thus the manufacturing cost of the blood glucose measurement device is significantly reduced.

In order to recognize the code value of the sensor strip, it is not necessary to design and implement an external circuit for separately recognizing the code value of the sensor strip on the inner substrate or the outside of the blood glucose measurement apparatus, So that the board design of the blood glucose measurement apparatus can be significantly improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an explanatory diagram illustrating a blood glucose measurement device for recognizing a code of a conventional sensor strip. FIG.
FIG. 2 is an explanatory view illustrating a blood glucose measurement device for automatically recognizing a code signal of a sensor strip according to the present invention. FIG.
FIG. 3 (ad) is an explanatory view for explaining an experimental example for obtaining a code using four input / output ports provided in the microcomputer of the present invention; FIG.
Fig. 4 (ad) is an explanatory diagram for explaining truth values corresponding to (ad) in Fig. 3;
(e) is an explanatory diagram for explaining a table summarizing the code values according to the result of summing the truth values of (ad) in Fig.
FIG. 5 (a) is an explanatory diagram for explaining an embodiment in which various code combination values of the sensor strip are implemented using the truth values of FIG. 4 (e).

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

The present invention comprises a sensor strip 3, in which a carbon electrode 1 having a plurality of code combination values is selectively printed on an electrode port 2 and shipped as shown in FIG. 2;

When the sensor strip 3 is inserted, various code combination values of the sensor strip 3 corresponding to the shape of the carbon electrode 1 printed on the electrode port 2 of the sensor strip 3 are automatically read, And a blood glucose measurement device main body 4 for calculating a blood glucose measurement value after correcting the sensing measurement deviation of the sensor strip 3.

The body 4 of the blood glucose measurement apparatus is loaded with various types of code combination values realized by the carbon electrode 1.

Next, the operation and effect of the apparatus of the present invention as described above will be described.

Here, the code combination values are calculated through various processes as shown in (a-d) of FIG. 3 and (a-e) of FIG.

1) of the four input / output ports of the microprocessor (not shown) provided in the blood glucose measurement device main body 4, And the remaining three ports are set to input ports having internal software pull-up resistors of the microprocessor. After outputting Low (GND) output to the P1 port, the remaining three port states are read and the port state is stored.

  2) Of the four input / output ports of the microprocessor, P2 is set as an output port and the remaining three ports are set as input ports having microprocessor internal software pull-up resistors as shown in FIG. 3 (b) . After outputting a low (GND) output to the P2 port, the remaining three port states are read and the port state is stored.

  3) Of the four input / output ports of the microprocessor, P3 is set as an output port and the remaining three ports are set as input ports having microprocessor internal software pull-up resistors as shown in FIG. 3 (c). After outputting a low (GND) output to the P3 port, the remaining three port states are read and the port state is stored.

  4) Of the four input / output ports of the microprocessor, P4 is set as an output port and the remaining three ports are set as input ports having a microprocessor internal software pull-up resistor, as shown in FIG. 3 (d). After outputting Low (GND) output to the P4 port, the remaining three port states are read and the port state is stored.

 5) As described above, P1, P2, P3, and P4 are sequentially output as GND, and the connected states among the four ports are read to divide the total into 11 numbers.

 6) The code number of the biosensor (strip) is determined according to the 11 kinds recognized through the above process.

4 (ad), various types of code combination values as shown in (ad) of FIG. 4 can be obtained. For example, in the case of FIG. 3 (a) The truth value as shown in (a) of FIG. 3, the truth value as shown in (b) of FIG. 3 in the case of FIG. 3 (b) The truth value is obtained as shown in FIG. 3 (d), and the truth value as shown in FIG. 4 (d) is obtained. 4 (e) is a table summarizing the code values according to the sum of the truth values of (a-d) of FIG.

Here, (a-k) of FIG. 5 is an embodiment in which various code combination values of the sensor strip 3 are implemented using the truth values of FIG. 4 (e) calculated as described above.

That is, the sensor strip 3 according to the present invention can be manufactured by forming the carbon strip 1 corresponding to 11 code combination values using the truth values of FIG. 4 (e) And selectively shipped to the port 2 to be shipped.

When the optional sensor strip 3 shipped for each manufacturer is mounted on the strip connector 5 of the blood glucose measurement device main body 4 as described above, The various code combination values of the sensor strip 3 according to the shape of the carbon electrode 1 printed on the sensor strip 2 are automatically read to correct the sensing measurement deviation of the sensor strip 3, 7).

Therefore, when the sensor strip 3 according to the present invention as described above is used, the sensor strip 3 is shipped while the code combination value is selected and printed for each manufacturer as described above, Since the code combination value by the carbon electrode 1 of the sensor strip 3 can be read irrespective of the manufacturer, an external circuit is separately provided to the blood glucose measurement device 4 in order to recognize the code of the sensor strip 3 There is no need to install.

That is, according to the present invention, when a sensor strip is manufactured, a carbon electrode having a plurality of code combination values is selected and printed on an electrode port of a sensor strip, and various types of code combination values The code value of the sensor strip is automatically read and processed by the installed blood glucose measuring device so that the code value of the sensor strip can be recognized without requiring an external circuit separately in the blood glucose measuring device, Since the code combination value is read and processed easily, it is not necessary to use an expensive code recognition circuit.

In order to recognize the code value of the sensor strip, it is not necessary to design and implement an external circuit for separately recognizing the code value of the sensor strip on the inner substrate or the outside of the blood glucose measurement device, The substrate can be easily designed.

1: carbon electrode 2: electrode port
3: sensor strip 4: blood glucose meter body
5: strip connector 6: key input part
7: Display

Claims (2)

A sensor strip in which carbon electrodes having a plurality of code combination values are selectively printed on an electrode port and shipped;
When the sensor strip is inserted, various cord combination values of the sensor strip corresponding to the shape of the carbon electrode printed on the electrode port of the sensor strip are automatically read to correct the sensed measurement deviation of the sensor strip, A blood glucose measurement device main body
Wherein the sensor strip is configured to detect the plurality of code combination values using a total number of 11 cases generated as GND outputs to respective ports by using four input / output ports of a microprocessor provided in the blood glucose measurement apparatus main body. Setting,
The main body of the blood glucose measuring apparatus stores a code combination value corresponding to the total number of 11 cases generated by using four input / output ports of the microprocessor, and reads the stored code combination value and the stored sensor combination And automatically recognizes a code signal of a sensor strip for detecting a code value for each manufacturer of the code combination value. The blood glucose measurement device according to claim 1, wherein the body of the blood glucose measurement apparatus includes all kinds of code combination values implemented by carbon electrodes.

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