TWM564160U - Physiological detecting device for automatically differentiating detection test piece calibration parameters and detection test piece thereof - Google Patents

Abstract

The present invention is a physiological detecting device, which comprises a body, a test strip slot, a measuring unit, a code detecting unit, a code parameter corresponding converting unit and an arithmetic unit, and the physiological detecting device uses a check. The test piece comprises a measuring electrode structure and a code electrode structure, wherein the detecting test piece is for inserting into the test piece slot, the measuring unit and the code detecting unit respectively for reading the measuring electrode structure and the code electrode a structure, wherein the operator obtains a quantity of the test signal and a code, and obtains a correction parameter corresponding to the code according to the code parameter corresponding to the conversion unit, and the operator can be integrated with the measurement signal by the correction parameter The operation obtains the corrected physiological signal, and accordingly, the creation can accurately measure without using the calibration parameter card, which is convenient to use, and has no problem of measuring error caused by misusing the parameter card.

Description

Physiological detecting device with automatic discrimination detecting test piece correction parameter and test piece thereof

The present invention relates to a physiological signal detector, and more particularly to a physiological detecting device capable of automatically discriminating a calibration parameter of a test strip.

For frail middle-aged and elderly people who are sick in bed for a long time, high blood pressure, diabetes, gout, cardiovascular obstruction, anemia, etc. are good diseases. Most middle-aged and elderly people have potential factors for inducing these diseases. The first time to find the symptoms, the elderly, patients must monitor their own physiological information such as blood pressure, blood sugar, cholesterol, uric acid, hemoglobin and blood oxygen at home, when the physiological information presents abnormal data, it can be properly disposed of immediately. To maintain good health.

Please refer to "Figure 1". At present, the test strip 1 and the interpreter 2 are available. The test strip 1 can detect various physiological information according to its type, insert it into the special interpretation machine 2, and then drop it into the user. The specimens, such as blood...etc., can be used to measure physiological information such as blood sugar, uric acid, heme, triglycerides and cholesterol.

Since the test strip 1 is affected by environmental and climatic temperatures and the like due to the enzyme raw material used in the production of the test piece 1, it directly affects the data at the time of detection, and in order to correctly detect and improve the accuracy, it needs to be corrected, so that it is manufactured. When the test piece 1 is tested, a corresponding calibration parameter card 3 (encoding module) is simultaneously manufactured, such as the Taiwan Patent No. I265677, which discloses a coding module, a biometric device and a method for operating the biometric device. The test strips 1 of different batches will have different calibration parameter cards 3, and the discriminator 2 needs to simultaneously insert the corresponding calibration parameter card 3 when using the test strips 1 of the batch number, and the discriminating machine 2 will be based on The calibration parameter recorded in the calibration parameter card 3 is combined with a measured number of measurement signals to integrate and generate accurate physiological signals.

Since the test strips 1 of different batch numbers have different calibration parameter cards 3, they cannot be mixed, otherwise the correctness of the measured physiological information will be affected. However, in practice, it is often forgotten to replace the correct calibration parameters. Card 3, or different batches of test strips 1 have been confused and difficult to distinguish and it is difficult to select the correct calibration parameter card 3, causing misuse and the like, which causes inconvenience in use and allows the measured physiological If the information loses accuracy, and the physiological information of the equivalent measurement is inaccurate, it will cause the user to misjudge the condition and have problems that endanger the health of the body.

Therefore, the main purpose of this creation is to expose a physiological detection device with automatic discrimination detection test piece calibration parameters, which can accurately measure physiological information without additionally inserting a calibration parameter card.

In order to achieve the above-mentioned creative purpose, the present invention is a physiological detecting device with automatic discriminating test piece correction parameters, which is used together with a test piece comprising a measuring electrode structure and a code electrode structure, the measuring piece The electrode structure is configured to drop into a sample, and the aspect of the code electrode structure corresponds to any one of the plurality of codes, and the code electrode structure has at least one determining electrode, and the at least one determining electrode is arranged side by side at one end of the detecting test piece. And the at least one determining electrode has an electrical connection state with respect to each other different codes.

The physiological detecting device comprises a body, a test strip slot, a measuring unit, a code detecting unit, a code parameter corresponding converting unit and an arithmetic unit, wherein the test piece slot is disposed on the body and is provided for The detecting test piece is inserted, the measuring unit is disposed in the body and is configured to read the measuring electrode structure to obtain a measuring signal. The code detecting unit is disposed in the body and is configured to read the code electrode structure. The code representative, the code parameter corresponding to the conversion unit is disposed in the body, and the corresponding relationship between the complex code and the plurality of correction parameters is recorded, the operator is disposed in the body, and electrically connected to the test strip slot, The measuring unit, the code detecting unit and the code parameter corresponding to the converting unit, so that the computing device obtains the measurement signal and the code, and the operator knows that the code corresponds to the code unit by the conversion unit The calibration parameter is such that the operator performs an integration operation with the measurement signal according to the calibration parameter to obtain a corrected physiological signal.

According to this, the creation of the creation of the parameter card is not necessary, and the use of the test strips of different batch numbers can be mixed, and the problem that the measurement card is misaligned without the parameter card misalignment can meet the requirements of use.

The detailed description of the present invention and the technical description are further illustrated by the following examples, but it should be understood that the following examples are for illustrative purposes only and should not be construed as limiting the invention.

Please refer to FIG. 2, FIG. 3, FIG. 4A and FIG. 4B. The present invention is a physiological detecting device 10, which is used together with a detecting test piece 20, and the test test piece 20 includes a measurement. The electrode structure 21 and the code electrode structure 22, the measuring electrode structure 21 and the code electrode structure 22 can be respectively located on the same upper and lower sides (double-sided structure) of the detecting test piece 20, so as to make full use of the space, the measuring electrode The structure 21 is for dropping into a sample (not shown), and the pattern of the code electrode structure 22 corresponds to any of the complex codes.

The physiological detecting device 10 includes a body 11, a test strip slot 12, a measuring unit 13, a code detecting unit 14, a code parameter corresponding converting unit 15 and an arithmetic unit 16, wherein the test chip slot 12 is disposed on the body 11 and is inserted into the test strip 20. The measuring unit 13 is disposed in the body 11 and is configured to read the measuring electrode structure 21 to obtain a measuring signal. The code detecting unit 14 is disposed in the body 11 and is configured to read the code represented by the code electrode structure 22. The code parameter corresponding conversion unit 15 is disposed in the body 11 and records the correspondence between the complex code and the complex correction parameter. The body 11 can be provided with a display 19 connected to the computing unit 16 and a control button set 18 for displaying operational messages and measurement results, and the control button set 18 is operable by the user.

The computing device 16 is disposed in the body 11 and electrically connected to the test strip slot 12, the measuring unit 13, the code detecting unit 14 and the code parameter corresponding converting unit 15 for the computing unit 16 to obtain The measurement signal is associated with the code, and the operator 16 knows the correction parameter corresponding to the code by the code parameter corresponding to the conversion unit 15, and thus the operator 16 performs the calibration signal according to the calibration parameter and the measurement signal. The operation is to obtain a corrected physiological signal. In addition, the body 11 can further be provided with a temperature measuring unit 17 connected to the computing unit 16, and the temperature measuring unit 17 can obtain an instantaneous ambient temperature for reference by the user.

As shown in FIG. 4C and FIG. 4D, the code electrode structure 22 may have at least one determining electrode 221, and the at least one determining electrode 221 is arranged side by side at one end of the detecting test piece 20, and The at least one determining electrode 221 has an electrical connection pattern respectively representing different codes, that is, the electrical connection state of the at least one determining electrode 221 can represent the code, as shown in FIG. 4D. It lists 8 kinds of electrical connection patterns of B1~B8, which can represent 8 codes (correction parameters). The measuring electrode structure 21 may include a working electrode 211 and at least one reference electrode 212. The working electrode 211 and the at least one reference electrode 212 are arranged side by side at one end of the detecting test piece 20, and the at least one reference electrode 212 has electrical connection patterns representing different detection modes, and the electrical connection mode of the at least one reference electrode 212 can represent the detection mode, as shown in FIG. 4C, which lists A1~A3 total 3 An electrical connection pattern that represents three detection modes.

Please refer to FIG. 5, which is a flow chart of the use of the present invention, which includes steps S1 to S9, which is a flow chart of the use of the creation. First, step S1: detecting the insertion of the test piece, the user will insert the test piece 20 to be inserted. The test strip slot 12. Next, in step S2, the detection mode detection is started, and the detection mode to be used is determined by the measurement unit 13 to obtain the electrical connection state between the at least one reference electrode 212, and is used for measuring, for example, blood glucose. Physiological information such as uric acid, cholesterol, triglycerides, etc. Then, in step S3, the correction parameter is obtained, and the code detecting unit 14 reads the electrical connection state of the at least one determination electrode 221, and further knows the code represented by the code, and the operator 16 uses the code again. The parameter corresponds to the conversion unit 15 to know the correction parameter corresponding to the code.

Next, in step S4, the physiological detecting device is turned on, and the physiological detecting device is turned on, and the measurement is prepared. Next, in step S5, it is detected whether or not the sample is dropped, and if so, step S6 is performed, and if not, the sample is dropped, and step S4 is performed again. Next, in step S6, the physiological detecting device counts down and obtains a measuring signal, which is a countdown period, and simultaneously obtains the measuring signal. Next, in step S7: integrating the calculation, the physiological signal is generated by using the calibration parameter and the measurement signal operation. Next, in step S8: whether the reciprocal is over, whether the reciprocal is over is detected, and if not, the process returns to step S6 and continues to count down, and the measurement signal is acquired again. If the reciprocal is over, step S9 is performed. The measured value is displayed, and the physiological signal is displayed on the display 19.

As mentioned above, this creation has at least the following advantages:

1. No need to use additional parameter cards, no parameter card missing, confusion, misplacement, etc.

2. Test strips of different batch numbers can be mixed to increase the convenience of use.

The above is only the preferred embodiment of the present invention, and is not intended to limit the scope of implementation of the present invention, that is, the equivalent changes and modifications according to the content of the patent application scope of the present invention should be the novel technology. category.

Conventional knowledge

1‧‧‧Test strips

2‧‧‧Reading machine

3‧‧‧ Calibration parameter card

This creation

S1~S9‧‧‧Steps

10‧‧‧ Physiological testing device

11‧‧‧ body

12‧‧‧ test strip slot

13‧‧‧Measurement unit

14‧‧‧Code detection unit

15‧‧‧ Code parameter corresponding conversion unit

16‧‧‧Operator

17‧‧‧Temperature measurement unit

18‧‧‧Control button set

19‧‧‧ Display

20‧‧‧Test strips

21‧‧‧Measurement electrode structure

211‧‧‧Working electrode

212‧‧‧ reference electrode

22‧‧‧ Code electrode structure

221‧‧‧Judgement electrode

Figure 1 is a structural diagram of a conventional interpretation machine. FIG. 2 is a schematic structural view of the physiological detecting device of the present invention. FIG. 3 is a schematic diagram showing the function of the artificial physiological detecting device. FIG. 4A is a schematic structural view of the measuring electrode of the artificial test strip. FIG. 4B is a schematic diagram showing the structure of the code electrode of the artificial test strip. FIG. 4C is a schematic view showing the state of the measuring electrode of the test strip. FIG. 4D is a schematic view showing the state of the code electrode of the test strip. Figure 5 is a flow chart of the creation operation.

Claims (5)

A physiological detecting device with automatic discriminating test piece calibration parameters is used with a test strip comprising a measuring electrode structure and a code electrode structure for dropping into a sample, the measuring electrode structure The aspect of the code electrode structure corresponds to any one of the plurality of codes, the physiological detecting device comprises: a body; a test piece slot, the test piece slot is disposed on the body, and the test piece is inserted; The measuring unit is disposed in the body and configured to read the measuring electrode structure to obtain a measuring signal; a code detecting unit, the code detecting unit is disposed in the body and configured to read the code electrode structure The code represents a conversion unit, the code parameter corresponding to the conversion unit is disposed in the body, and records the correspondence between the complex code and the complex correction parameter; and an operator, the operator is disposed in the body Internally, electrically connecting the test strip slot, the measuring unit, the code detecting unit and the code parameter corresponding conversion unit, so that the computing unit obtains the measurement signal and the code, and By the operator parameter corresponding to the code conversion unit and that the code corresponding to the correction parameter to the correction parameter based on the calculation performed to obtain a signal measuring the physiological signal after correction. The physiological detecting device with the automatic discriminating test strip correction parameter according to the first aspect of the patent application, wherein the body is provided with a display and a control button group connected to the arithmetic unit. The physiological detecting device for automatically determining the test piece correction parameter according to the first aspect of the patent application, wherein the body further comprises a temperature measuring unit connected to the computing device. A test strip comprising: a measuring electrode structure for dropping into a sample; and a code electrode structure, the measuring electrode structure and the code electrode structure respectively located on the detecting piece On the upper and lower sides, the aspect of the code electrode structure corresponds to any one of the complex codes, and the code electrode structure has at least one determining electrode, the at least one determining electrode is arranged side by side at one end of the detecting test piece, and the at least one determining electrode There are electrical connections between them that represent different codes. The test strip of claim 4, wherein the measuring electrode structure comprises a working electrode and at least one reference electrode, wherein the working electrode and the at least one reference electrode are arranged side by side at one end of the detecting test piece. And the at least one reference electrode has an electrical connection pattern representing different detection modes with each other.