CN204165979U - Electric resistance structure, identification massaging device and biology sensor - Google Patents

Abstract

The utility model relates to a kind of electric resistance structure, identification massaging device and biology sensor.A kind of electric resistance structure comprises: the first electrode; Second electrode; Multiple first resistive element, first resistive element one end described in each is connected to described first electrode and the other end is connected to described second electrode; First fracture, described first electrode is divided into Part I and Part II by described first fracture, and described first fracture is between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode.

Description

Electric resistance structure, identification massaging device and biology sensor

Technical field

The utility model relates to a kind of electric resistance structure, identification massaging device and biology sensor, the electric resistance structure particularly on the biology sensor of medical test, identification massaging device and biology sensor.

Background technology

Biosensor technology such as biological sensing test paper is widely used in bedside and detects (Point of Care Test, POCT) field.For blood sugar test technology, owing to having the convenient advantage with checking in time of operation, blood glucose meter is widely used as a kind of instrument detecting blood sugar.Blood glucose meter is roughly divided into the blood glucose meter utilizing photochemistry principle to detect and the blood glucose meter utilizing electrochemical principle to detect.In photochemistry test paper, the chemical substance produced after enzyme on the photochemistry biological sensing test paper of glucose in blood and blood glucose meter reacts causes the change of mark substance color or absorption/emission wavelength, by blood glucose meter, the change of color change or absorption/emission wavelength is converted to corresponding blood sugar concentration numerical value; In Electrochemical blood glucose test, after the enzyme on the Electrochemcial biological sensing test paper of the glucose in blood and blood glucose meter produces electrochemical reaction, disengaging by media electronic, is converted to blood sugar concentration numerical value by blood glucose meter by curent change.

In actual applications, small difference deposited by biology sensor due to each batch, or same detecting instrument may in conjunction with different biology sensors for detecting dissimilar analysis thing (as whole blood, urine etc.), or same biology sensor may be applied on different detecting instruments, need the biology sensor corresponding to each batch and each kind that different correction parameters is set.

For blood sugar electrochemical test bar, the difference between the different surface state of working electrode and the enzyme amount in contrast electrode volume, area, reaction zone, reaction electrode etc. batch may be there is between each batch, all can affect testing result.Before dispatching from the factory, manufacturer can set one group of specific correction parameter values according to the product of each lot number, to confirm that testing result is correct.In addition, the raw manufacturer of some biology sensor can by customer demand, and produce OEM test-strips with the design of same biosensor test strip, supporting different detecting instrument uses, and test-strips needs guarantee can not instrument cross-reference between two kinds of detecting instruments.Also the producer had, only can detect different analysis things with a detecting instrument, and therefore before detection, detecting instrument must utilize and first judge, to guarantee that testing result is correct detection thing type.

Generally adopt correcting chip that correction parameter is set at present on the market, namely often criticize biological sensing test paper and be equipped with corresponding correcting chip, in chip, prestore the correction parameter of this batch.As long as this correcting chip is inserted detecting instrument by user in use, re-use the test paper of supporting lot number, test result accurately can be obtained.But in actual applications, client but forgets this action often, cause measuring the result drawn inaccurate.

In order to address this problem, U.S. Patent application US20100170791A1 discloses a kind of electrode design, the different resistance ratio between the multiple contact of this electrode, can be invested different identification information, in other words, can provide different correction parameters.Detecting instrument can be connected any two contacts of this electrode design by user in use, obtains different correction parameters, and inputs to detecting instrument realization correction.But the disclosure weak point is, if desired prestore a large amount of correction parameters, then this biology sensor just needs to design a lot of contact, and corresponding detecting instrument also needs to increase contact, and the cost of product is increased.

Utility model content

One of object of the present disclosure is to provide a kind of electric resistance structure of novelty, can be used for identification massaging device and biology sensor.Another object of the present disclosure is to provide a kind of identification massaging device and biology sensor, adopts above-mentioned Novel resistor structure.

Other objects of the present disclosure, characteristic and advantage become obvious by by detailed description below, or the acquistion partially by practice of the present disclosure.

According to some embodiments, a kind of electric resistance structure comprises: the first electrode; Second electrode; Multiple first resistive element, first resistive element one end described in each is connected to described first electrode and the other end is connected to described second electrode; First fracture, described first electrode is divided into Part I and Part II by described first fracture, and described first fracture is between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode.

According to some embodiments, electric resistance structure also comprises; 4th electrode, described 4th electrode is connected with the described Part I of described first electrode; First contact, is connected with the described Part II of described first electrode; Second contact, with described second Electrode connection; And the 3rd contact, with described 4th Electrode connection.

According to some embodiments, the described Part II of described first electrode also has N number of second fracture, N be greater than 0 natural number, described N number of second fracture is each between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode, and described Part I is divided into N+1 part by described N number of second fracture.

According to some embodiments, described second electrode also have M the 3rd fracture, M be greater than 0 natural number, described M the 3rd fracture is each between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described second electrode, and described second electrode is divided into M+1 part by individual 3rd fracture of described M.

According to some embodiments, electric resistance structure also comprises: the 4th electrode; Multiple second resistive element, second resistive element one end described in each is connected to described second electrode or described first electrode and the other end is connected to described 4th electrode.

According to some embodiments, wherein said second electrode and described 4th electrode one of at least on there is multiple first fracture, described multiple first fracture is each between adjacent two the first resistive elements or the second resistive element or disconnect the connection of at least one first resistive element or the second resistive element and described second electrode.

According to some embodiments, described multiple first resistive element and described multiple second resistive element are symmetrical arranged.According to some embodiments, corresponding first resistive element and the second resistive element form as one.According to some embodiments, a kind of identification massaging device comprises: the electric resistance structure described in aforementioned any one, wherein at least part of described multiple first resistive element has rectilinear form.

According to some embodiments, a kind of biology sensor comprises: biology sensor body, comprises being arranged on working electrode on insulativity base plate and to electrode; And aforesaid identification massaging device, be positioned on described insulativity base plate.

According to first aspect of the present disclosure, a kind of electric resistance structure comprises: the first electrode; Second electrode; Multiple first resistive element, first resistive element one end described in each is connected to described first electrode and the other end is connected to described second electrode; First fracture, described first electrode is divided into Part I and Part II by described first fracture, and described first fracture is between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode.

According to second aspect of the present disclosure, on the basis of first aspect, also comprise; 4th electrode, described 4th electrode is connected with the described Part I of described first electrode; First contact, is connected with the described Part II of described first electrode; Second contact, with described second Electrode connection; And the 3rd contact, with described 4th Electrode connection.

According to the third aspect of the present disclosure, first or second aspect basis on, the described Part II of described first electrode also has N number of second fracture, N be greater than 0 natural number, described N number of second fracture is each between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode, and described Part I is divided into N+1 part by described N number of second fracture.

According to fourth aspect of the present disclosure, first or second aspect basis on, described second electrode also have M the 3rd fracture, M be greater than 0 natural number, described M the 3rd fracture is each between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described second electrode, and described second electrode is divided into M+1 part by individual 3rd fracture of described M.

According to the 5th aspect of the present disclosure, first or second aspect basis on, also comprise: the 4th electrode; Multiple second resistive element, second resistive element one end described in each is connected to described second electrode or described first electrode and the other end is connected to described 4th electrode.

According to the 6th aspect of the present disclosure, on basis in the 5th, described second electrode and described 4th electrode one of at least on there is multiple first fracture, described multiple first fracture is each between adjacent two the first resistive elements or the second resistive element or disconnect the connection of at least one first resistive element or the second resistive element and described second electrode.

According to the 7th aspect of the present disclosure, on the basis in the 5th, described multiple first resistive element and described multiple second resistive element are symmetrical arranged.

According to eighth aspect of the present disclosure, on the basis in the 7th, corresponding first resistive element and the second resistive element form as one.

According to the 9th aspect of the present disclosure, first or second aspect basis on, described multiple first resistive element is mutually the same.

According to the tenth aspect of the present disclosure, first or second aspect basis on, described multiple first resistive element comprises the multiple resistor stripes be set parallel to each other.

According to the 11 aspect of the present disclosure, first or second aspect basis on, described multiple first resistive element comprises at least one resistor disc.

According to the 12 aspect of the present disclosure, first or second aspect basis on, the size of described multiple first resistive element of part is different from the size of other the first resistive elements.

According to the 13 aspect of the present disclosure, a kind of identification massaging device comprises: as the electric resistance structure any one of the first to ten two aspect, wherein at least part of described multiple first resistive element has rectilinear form.

According to fourteenth aspect of the present disclosure, a kind of identification massaging device comprises: as the electric resistance structure any one of the first to ten two aspect, wherein at least part of described multiple first resistive element has curved shape.

According to the 15 aspect of the present disclosure, a kind of biology sensor comprises: biology sensor body, comprises and is arranged on working electrode on insulativity base plate and to electrode, is at least provided with reaction reagent layer at working electrode with on one of electrode; And as the identification massaging device of the 13 or 14 aspects, be positioned on described insulativity base plate.

According to the 16 aspect of the present disclosure, on basis in the 15, described identification massaging device and described working electrode and electrode is positioned to the similar face of described insulativity base plate, described identification massaging device and described working electrode and to electrode electrical isolation or with described working electrode be connected one of electrode.

According to the 17 aspect of the present disclosure, on the basis in the 15, described identification massaging device and described working electrode and electrode is positioned to the different surfaces of described insulativity base plate.

The electric resistance structure, electric resistance structure unit, identification message unit, the identification massaging device that propose according to the disclosure and biosensor structure is simple, carry information enriches, can reduce cost, reduce processed complex degree.

Accompanying drawing explanation

Fig. 1 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Fig. 2 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Fig. 3 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Fig. 4 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Fig. 5 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Fig. 6 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Fig. 7 A and Fig. 7 B is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Fig. 8 A to Fig. 8 D is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Fig. 9 A to Fig. 9 E is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Figure 10 is a kind of schematic diagram of biology sensor of detect analytes.

Figure 11 is the schematic diagram with the biology sensor of identification massaging device according to the disclosure one embodiment.

Figure 12 is the schematic diagram with the biology sensor of identification massaging device according to the disclosure one embodiment.

Figure 13 is the schematic diagram with the biology sensor of identification massaging device according to the disclosure one embodiment.

Figure 14 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Figure 15 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Figure 16 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Figure 17 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Figure 18 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Figure 19 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Figure 20 is the schematic diagram of the electric resistance structure according to the disclosure one embodiment.

Figure 21 schematically shows the variant according to electric resistance structure of the present disclosure and identification massaging device.

Figure 22 schematically shows the variant according to electric resistance structure of the present disclosure and identification massaging device.

Figure 23 schematically shows the variant according to electric resistance structure of the present disclosure and identification massaging device.

Figure 24 schematically shows the decomposition chart of the biology sensor according to some embodiments of the disclosure.

Embodiment

More fully embodiment is described referring now to accompanying drawing.But embodiment can be implemented in a variety of forms, and should not be understood to be limited to embodiment set forth herein; On the contrary, these embodiments are provided to make the disclosure comprehensively with complete, and the design of embodiment will be conveyed to those skilled in the art all sidedly.In the drawings, in order to clear, exaggerate the thickness of region and layer.Reference numeral identical in the drawings represents same or similar part, thus can omit their repeated description.

In addition, described feature, structure or characteristic can be combined in one or more embodiment in any suitable manner.In the following description, provide many details thus provide fully understanding embodiment of the present disclosure.But, one of skill in the art will appreciate that and can put into practice technical scheme of the present disclosure and not have in described specific detail one or more, or other method, constituent element, material etc. can be adopted.In other cases, known features, material or operation is not shown specifically or describes to avoid fuzzy each side of the present disclosure.

The exemplary embodiment embodying disclosure feature & benefits will describe in detail in the following description.Be understood that the disclosure can have various changes on different embodiments, it neither departs from the scope of the present disclosure, and explanation wherein and accompanying drawing are the use when explain in itself, and is not used to limit the disclosure.

The disclosure proposes a kind of electric resistance structure and comprises the unit of this electric resistance structure or device and biology sensor, by electrical parameter corresponding to the position of different fractures, thus can produce different codings, for detecting instrument.Be described for different embodiments below.

First embodiment

Figure 14 shows that the electric resistance structure shown in first embodiment of the present disclosure, as shown in figure 14, this electric resistance structure comprises the first electrode 1, second electrode 2 and multiple first resistive element 3.Multiple first resistive element 3 is connected between the first electrode 1 and described second electrode 2.This electric resistance structure also comprises the first contact 21 be connected with the first electrode 1 and the second contact 22 be connected with the second electrode 2.First electrode 1 has the first fracture 11, first fracture 11 and first electrode 1 can be divided into Part I 111 and Part II between two such as adjacent the first resistive elements 3, but the disclosure is not limited thereto; First contact 21 is connected with Part II, has the first electrical parameter R1 between the first contact 21 and the second contact 22.First electrical parameter R1 can be such as resistance value.But the disclosure is not limited thereto.Such as, the first electrical parameter R1 also can be externally measured system access first contact 21 and the second contact 22 time the resistance value, magnitude of voltage or the current value that obtain.All similar to the discussion of electrical parameter below.It should be noted that in the present embodiment and following embodiment, Part I 111 all refers to part drawing being positioned at relatively top, and Part II 112 refers to part drawing being positioned at relatively below.

In the present embodiment, as shown in figure 14, when detecting instrument connects the first contact 21 and the second contact 22, just detect the first electrical parameter R1, this first electrical parameter R1 changes along with the difference of the first fracture 11 position.Such as, first electrical parameter R1 is resistance value in the present embodiment, when the first fracture 11 change in location, by the first electrode 1, the many electrical return being arranged in below the first fracture 11 first resistive element 3 in parallel and the second electrode 2 and forming, the value of resistance can change along with the change of the radical of the first resistive element 3 of parallel connection, and therefore the difference of the position of the first fracture 11 can cause the difference of the first electrical parameter R1.

Such as, but the first above-mentioned electrical parameter R1 can not be limited to resistance value, and also can be other electrical parameter, current value, magnitude of voltage etc., the disclosure limit.

In the present embodiment, shown in Figure 14, the first electrode 1 and the second electrode 2 are electrode arranged in parallel, and multiple first resistive element 3 is for being set in parallel in the electrode between the first electrode 1 and the second electrode 2.But the disclosure is not limited thereto.Easy to understand, the first electrode 1 and the second electrode 2 also can not be parallel to each other.First electrode 1 and the second electrode 2 are longitudinal electrode, and the first resistive element 3 is multiple transverse electrode.Multiple first resistive element 3 is mutually the same, also can be different from each other, is mutually the same electrode in the present embodiment, and namely the parameter such as material, size, resistivity of each the first resistive element 3 is all identical.

After detecting instrument detects the first electrical parameter R1, just corresponding encoded can be drawn according to the formulae discovery of detecting instrument storage inside, or directly draw coding according to the first electrical parameter R1, the information that the correspondence of different codings is different, the test paper of such as corresponding different batches, detect the test paper etc. of dissimilar sample, thus provide different correction parameters by detecting instrument, make testing result more accurate.

Second embodiment

Fig. 6 is the second embodiment of disclosure electric resistance structure, and in the present embodiment, compared to the first embodiment shown in Figure 14, electric resistance structure also has the 4th electrode 4 and the 3rd contact 23.4th electrode 4 is connected with the Part I 111 of the first electrode 1, and the 3rd contact 23 is connected with the 4th electrode 4.First contact 22, contact 21, second can be connected with detecting instrument with the 3rd contact 23.

When Electrode connection first contact 21 and second contact 22 of detecting instrument, the first electrode 1, between multiple first resistive element 3, second electrodes 2 parallel with one another of the first fracture less than 11, there is the first electrical parameter R1;

When Electrode connection second contact 22 and the 3rd contact 23 of detecting instrument, the second electrode 2, between multiple first resistive element 3 parallel with one another and the 4th electrode 4 of the first fracture more than 11, there is the second electrical parameter R2;

R1 and R2 value can be different along with the difference of fracture 11 position on the first electrode 1, therefore also can correspondingly change.

First resistive element number is natural number, and is at least 2, changes resistance, R1, R2 value is changed, such as shown in figures 8 a-8d by the area, width, material etc. of the first resistive element changing each or part.

The material of the first resistive element 3 is different and/or the different conductive parameters that causes of conductive area is different.Wherein, if the remaining unchanged of the first fracture 11, but two the first resistive elements 3 are processed as two kinds of different electrodes of conductive material or the electrode of the different distribution of same material size, thus change R1 and R2 value, such as shown in Figs. 9 A-9 E.

3rd embodiment

Figure 15 shows that the electric resistance structure shown in third embodiment of the present disclosure, as shown in figure 15, compared to the second embodiment, in the present embodiment, second electrode 2 also has the 3rd fracture 13, second electrode 2 between adjacent two the first resistive elements 3, and is divided into Part I 121 and Part II 122, second contact 22 to be connected with the Part I 121 of the second electrode 2 by the 3rd fracture 13.

In the present embodiment, second electrical parameter R2 changes along with the difference of the position of the first fracture 11 and the 3rd fracture 13, and the first resistive element number that the first resistive element number that wherein the first fracture 11 top 111 part connects is connected with the 3rd fracture 13 top 131 part is unequal.

After detecting instrument detects the first electrical parameter R1 between the first contact 21 and the second contact 22 and the second electrical parameter R2 between the 3rd contact and the second contact, just corresponding encoded can be drawn according to the formulae discovery of detecting instrument storage inside, the information that the correspondence of different codings is different, the test paper of such as corresponding different batches, detect the test paper etc. of dissimilar sample, thus provide different correction parameters by detecting instrument, make testing result more accurate.

4th embodiment

Figure 16 shows that the electric resistance structure shown in fourth embodiment of the present disclosure, as shown in figure 16, compared to the 3rd embodiment, in the present embodiment, electric resistance structure also comprises the 5th electrode 5 and the 4th contact 24,5th electrode 5 is connected with the Part I 121 of the second electrode 2, and the 4th contact 24 is connected with the 5th electrode 5.In the present embodiment, except there is the first electrical parameter R1 between the first contact 21 and the second contact 22, having except the second electrical parameter R2 between the first contact 21 and the 3rd contact 23, other electrical parameters can also be had between first contact 21 and the 4th contact 24, these electrical parameters can change along with the change of fracture site, so that the combination by different electrical parameters expands more coding, corresponding different information.

5th embodiment

Fig. 7 A and Fig. 7 B is the schematic diagram of the 5th embodiment of disclosure electric resistance structure.In the present embodiment, as shown in Figure 7 A, compared to the electric resistance structure shown in the second embodiment in Fig. 6, on first electrode 1 of the present embodiment except there is the first fracture 11, also there is the second fracture 12.First electrode 1 is divided into the Part I 111 being positioned at top, the Part II 113 being positioned at below and is positioned at middle Part III 112 by the first fracture 11 and the second fracture 12.In addition, one end that Part III can be connected with the 7th electrode the 7, seven electrode 7 can be connected with the 6th contact 26.

According to Fig. 7 A, configurable a kind of electric resistance structure is used for information identifying device or other devices.This electric resistance structure can be configured to and comprises: the first electrode 1; Second electrode 2; Multiple first resistive element 3, each first resistive element 3 one end is connected to the first electrode 1 and the other end is connected to the second electrode 2; N number of fracture 11 and 12, first electrode 1 is divided into N+1 part 111,112 and 113 by N number of fracture 11 and 12, N number of fracture 11 and 12 is each between adjacent two the first resistive elements 3 or disconnect the connection of at least one first resistive element 3 and the first electrode 1, N be greater than 1 natural number; First contact 21; 6th contact 26; And the 3rd contact 23.

First contact 21, the 6th contact 26 and the 3rd contact 23 are each is connected to one of N+1 part 111,112 and 113.According to some embodiments, at least one of them is also connected to one of N+1 part 111,112 and 113 by an electric resistance structure for the first contact 26, contact 21, second or the 3rd contact 23.This electric resistance structure at least can comprise a resistive element.Not shown electric resistance structure in Fig. 7 A, but can refer to Figure 21-23.

6th embodiment

Figure 17-18 is depicted as the electricity structure shown in the disclosure the 6th embodiment.As shown in figure 17, compared to the first embodiment, the electric resistance structure in the present embodiment also comprises the 6th electrode 6 and the 5th contact the 25, six electrode 6 and to connect respectively and by each the first resistive element 3.5th contact 25 is connected with the 6th electrode 6.

First electrode 1 has the first fracture 11, first fracture 11 is divided into Part I 111 and Part II 112, first contact 21 to be connected with the Part II 112 of the first electrode 1 between adjacent two the first resistive elements 3 and by the first electrode 1.As shown in figure 18, the second electrode 2 has the second fracture 12, second fracture 12 between adjacent two the first resistive elements 3.In first fracture 11 and the second fracture 12, a fracture is had at least to exist.

Electrical parameter R1 can be had between first contact 21 and the 5th contact 25 and electrical parameter R3 can be had between the second contact 22 and the 5th contact 25.

The electrical parameter calculating S=K*R1/R3, R1 or R3 can change along with the change in location of fracture, thus expands more coding by the combination of different electrical parameters, corresponding different information.

7th embodiment

Figure 19-20 is the electricity structure shown in the disclosure the 7th embodiment.As shown in figure 19, compared to the 6th embodiment, the electric resistance structure in the present embodiment also comprises the 4th electrode 4 and the 3rd contact 23.4th electrode 4 is connected with the Part I 111 of the first electrode 1, and the 3rd contact 23 is connected with the 4th electrode 4.Wherein, there is between the first contact 21 and the 5th contact 25 first electrical parameter R1, there is between the 3rd contact 23 and the 5th contact 25 second electrical parameter R2, there is between the second contact 22 and the 5th contact 25 the 3rd electrical parameter R3.In the present embodiment, these electrical parameters above-mentioned can change along with the change in location of fracture, thus expand more coding by the combination of different electrical parameters, corresponding different information.

8th embodiment

Fig. 1-3 is the disclosure the 8th embodiment, demonstrates the schematic diagram of the electric resistance structure of the 8th embodiment.As shown in Figure 1, compared to the 7th embodiment, the electric resistance structure in the present embodiment also comprises the 5th electrode 5 and the 4th contact 24.5th electrode 5 is connected with the Part I 121 of the second electrode 2, and the 4th contact 24 is connected with the 5th electrode 5.There is between 4th contact 24 and the 5th contact 25 the 4th electrical parameter R4, first electrical parameter R1, the second electrical parameter R2, the 3rd electrical parameter R3 and the 4th electrical parameter R4 can change along with the change in location of the first fracture 11 and the second fracture 12, thus expand more coding by the combination of different electrical parameters, corresponding different information.

In the present embodiment, many first resistive elements 3 be arranged in parallel and mutually the same, and the 6th electrode 6 by the mid point of each root first resistive element 3 length direction, that is, is that each root first resistive element 3 is divided into isometric two parts.Also can Length discrepancy in practice.

First electrode 1, second electrode 2, the 4th electrode 4, the 5th electrode 5 are connected with detecting instrument with the 5th contact 25 by the first contact 22, contact 21, second, the 3rd contact 23, the 4th contact 24 with the 6th electrode 6, by by the Electrode connection of detecting instrument in different contacts, to obtain corresponding control information parameter, below illustrate.

R1-R4 can change along with the change in location of the first fracture 11 and the second fracture 12, thus expands more coding by the combination of different electrical parameters, corresponding different information.

When fracture site is constant, the 6th electrode position, not at the mid point of the first resistive element, causes the first resistive element left and right portions of resistance different, also can change electrical parameter Rn value, thus changes Sn value.

The embodiment of identification massaging device

The disclosure proposes a kind of identification massaging device, comprises insulativity base plate and is arranged on the electric resistance structure on insulativity base plate.Wherein electric resistance structure can be the electric resistance structure of above-described embodiment.Below citing is described.

First of identification massaging device implements aspect

Implement in aspect at first of identification massaging device, such as be described for Fig. 1 embodiment, composition graphs 1 can be found out, in the 8th embodiment, between the 3rd contact 23 and the 5th contact 25, there is the first electrical parameter R1, there is between first contact 21 and the 5th contact 25 second electrical parameter R2, there is between second contact 22 and the 5th contact 25 the 3rd electrical parameter R3, there is between the 4th contact 24 and the 5th contact 25 the 4th electrical parameter R4

After the identification massaging device of the disclosure the 8th embodiment is connected by electrode and contact with detecting instrument, the resistance value that detecting instrument records electrode loop is Rn and R ' n, obtains resistance ratio Sn by equation, as follows:

$\mathrm{Sn}=\mathrm{Kn}*\frac{\mathrm{Ra}}{\mathrm{Rb}}$

Wherein n=1-4, Sn represents resistance ratio, Kn represents correction factor, and wherein correction factor is that the ratio obtained due to actual process can have difference with theoretical value, and the correction factor obtained by test of many times makes actual close theory, Ra and Rb represents any two values in above-mentioned R1-R4 respectively, a=1-4, b=1-4, a ≠ b, have 12 kinds of array modes, as follows:

$\begin{array}{cc}S1=K1*\frac{R1}{R2}& S7=K7*\frac{R2}{R4}\end{array}$

$\begin{array}{cc}S2=K2*\frac{R3}{R4}& S8=K8*\frac{R3}{R1}\end{array}$

$\begin{array}{cc}S3=K3*\frac{R1}{R3}& S9=K9*\frac{R3}{R2}\end{array}$

$\begin{array}{cc}S4=K4*\frac{R1}{R4}& S10=K10*\frac{R4}{R1}\end{array}$

$\begin{array}{cc}S5=K5*\frac{R2}{R1}& S11=K11*\frac{R4}{R2}\end{array}$

$\begin{array}{cc}S6=K6*\frac{R2}{R3}& S12=K12*\frac{R4}{R3}\end{array}$

Wherein above-mentioned K1, K2....K12 is respectively correction factor.

In actual applications, some S values or the combination of multiple S value can be selected as required to give identification information.Such as, detecting instrument can select corresponding technical parameter etc. according to different S1 values, also can select corresponding technical parameter etc. according to the combination of S1 value and S2 value.As a rule, as according to above-mentioned formulae discovery, generally to need in sense circuit milli uncorrelated 2 groups of S1, S2 as the simplest mode of the best.

Production batch, different correction parameter correction equation, the supporting INSTRUMENT MODEL different according to biology sensor, or the analyte measured is different, the electrode of detecting instrument can connect different contacts, thus the resistance ratio S1 to S12 that identification massaging device provides is also different, detecting instrument is according to the information of different S1 to S12 and combination thereof, select corresponding technical parameter, finally show that the analysis quality testing survey of any type is carried out in testing result or judgement.

In addition, the disclosure is not limited to above-mentioned example.Such as, in the first contact 21 to the 5th contact 25, between any two contacts, all can have an electrical parameter, therefrom can choose any two parameters being suitable for utilizing above-mentioned formula to carry out encoding to be encoded.

Shown in composition graphs 2, when the position of change first fracture 11 and/or the second fracture 12, then above-mentioned Ra and Rb there occurs change, thus each Sn there occurs change, thus Sn be there has also been corresponding change by the identification information given.

As depicted in figs. 1 and 2, in this 8th embodiment, the resistance value of each the first resistive element 3 is roughly the same, is such as R ', and the resistance of the first electrode 1, second electrode 2, the 4th electrode 4, the 5th electrode 5 and the 6th electrode 6 is ignored, then

$S1=K1*\frac{R1}{R2}=K1*\frac{\frac{1}{\left(\frac{1}{\frac{R^{,}}{2}}\right)*x_1}}{\frac{1}{\left(\frac{1}{\frac{R^{,}}{2}}\right)*x_2}}=K1*\frac{x_2}{x_1}$

Wherein x1 represents the number of the first resistive element 3 of the loop process between the 3rd contact 23 and the 5th contact 25, and x2 represents the number of the first resistive element 3 of the loop process between the first contact 21 and the 5th contact 25.In like manner,

$S2=K2*\frac{R3}{R4}=K2*\frac{\frac{1}{\left(\frac{1}{\frac{R^{,}}{2}}\right)*x_3}}{\frac{1}{\left(\frac{1}{\frac{R^{,}}{2}}\right)*x_4}}=K2*\frac{x_4}{x_3}$

Wherein x3 represents the number of the first resistive element 3 of the loop process between the second contact 22 and the 5th contact 25, and x4 represents the number of the first resistive element 3 of the loop process between the 4th contact 24 and the 5th contact 25.

Therefore, can find out when each the first resistive element 3 resistance is substantially identical, the ratio of the resistance value between different circuit equals the inverse of the radical of the first resistive element 3 in parallel in this loop.Certainly, the disclosure is not as limit.When the radical not by resistive element directly obtains ratio, the resistance value obtained by calculating or emulation is to obtain ratio.

S value can also be set to the numerical value with certain error scope, and such as its error range is ? scope in, the same group technique parameter of the equal choice for use of instrument is carried out detection and result and is calculated.

Second of identification massaging device implements aspect

Shown in composition graphs 3, when each first resistive element 3 is divided into two sections of Length discrepancy by the 6th electrode 6, in the 8th embodiment, S value also there occurs change, thus reaches the object of identification breath.

For example, when the first resistive element 3 is 3:1 by the length ratio that the 6th electrode 6 divides, if 1 unit resistance is n, then actual resistance is that 3n:n then can calculate S3 in the following way:

$S3=K3*\frac{R1}{R3}=K3*\frac{\frac{1}{\left(\frac{1}{3n}\right)*x_1}}{\frac{1}{\left(\frac{1}{n}\right)*x_3}}=K3*\frac{3x_3}{x_1}$

The 3rd of identification massaging device implements aspect

As shown in Figure 6, after the identification massaging device shown in disclosure Fig. 6 is electrically connected with contact by electrode with detecting instrument, detecting instrument calculates S1 according to R1 and R2, and according to different S1 value informations, select corresponding technical parameter, finally draw testing result or judge detecting instrument model or which kind of carries out to analyze quality testing survey.Wherein S1 can calculate according to the following equation:

$S1=K1*\frac{R1}{R2}=K1*\frac{\frac{1}{R^{,}*x_1}}{\frac{1}{R^{,}*x_2}}=K1*\frac{x_2}{x_1}$

The 4th of identification massaging device implements aspect

Shown in composition graphs 7A and Fig. 7 B, due to the increase of fracture, R1 and R2 value can be different along with the difference of first fracture 11, second fracture 12 position on electrode, therefore, S1=K1*R1/R2 also can correspondingly change, and after the contact of the electric resistance structure described in disclosure Fig. 7 is electrically connected with detecting instrument, instrument is according to different S1 value informations, select corresponding technical parameter, finally draw testing result or judge detecting instrument model or which kind of carries out to analyze quality testing survey.Or the electric resistance structure in the present embodiment also can be reduced to shown in Fig. 7 B further, namely eliminate many first resistive elements 3 of the Part III being connected to the first electrode 1, the 7th electrode 7 and the 6th contact 26 compared to Fig. 7 A.User still can by by Electrode connection first contact 21 of detecting instrument and the second contact 22 or be connected the second contact 22 and the 3rd contact 23 and detect R1 and R2, detecting instrument calculates S1 according to R1 and R2, and according to different S1 value informations, select corresponding technical parameter, finally draw testing result or judge detecting instrument model or which kind of carries out to analyze quality testing survey.Wherein S1 can be drawn by following formulae discovery:

$S1=K1*\frac{R1}{R2}=K1*\frac{\frac{1}{R^{,}*x_1}}{\frac{1}{R^{,}*x_2}}=K1*\frac{x_2}{x_1}$

The 5th of identification massaging device implements aspect

Shown in composition graphs 8A to Fig. 8 D, in Fig. 8 A to Fig. 8 D, R1 and R2 value can be different along with the difference of first fracture 11, second fracture 12 position on electrode, therefore S1 also can correspondingly change, after the identification massaging device described in disclosure 8A to Fig. 8 D is electrically connected by contact with detecting instrument, detecting instrument, according to different S1 value informations, selects corresponding technical parameter, finally draws testing result or judges detecting instrument model or which kind of carries out to analyze quality testing survey.

Assuming that 2 pieces of area ratio up and down of Fig. 8 B are 1:2, then

$S1=K1*\frac{R1}{R2}=K1*\frac{2}{1}=2K1$

The 6th of identification massaging device implements aspect

Shown in composition graphs 9A to Fig. 9 E, be described for Fig. 9 A, such as relatively top first resistive element 3 is 1:2 with the ratio of the area of relative first resistive element 3 on the lower, and the ratio of conductivity is 1:3, then R1:R2=6:1,

$S1=K1*\frac{R1}{R2}=K1*\frac{6}{1}=6K1$

Again for example, for Fig. 9 D, assuming that the material conductivity ratio 1:3 of upper and lower two the first resistive elements 3, below single first resistive element 3 resistance be n, bottom electrode block area is 20 times of single first resistive element area below, then

$S1=K1*\frac{R1}{R2}=K1*\frac{\frac{1}{\left(\frac{1}{3n}\right)*x_1}}{\frac{1}{\left(\frac{1}{n}\right)*x_2+\left(\frac{1}{\frac{n}{20}}\right)}}=K1*\frac{3(20+x_2)}{x_1}$

Production batch, different correction parameter correction equation, the supporting INSTRUMENT MODEL different according to biology sensor, or the analyte measured is different, the electrode of detecting instrument can connect different contacts, thus the resistance ratio Sn that identification massaging device provides is also different, detecting instrument is according to the information of different Sn and combination thereof, select corresponding technical parameter, finally show that the analysis quality testing survey of any type is carried out in testing result or judgement.

Figure 21-23 illustrates the variant according to electric resistance structure of the present disclosure and identification massaging device.

As shown in figure 23, recognize that massaging device obtains by carrying out modification and/or combination to the structure shown in Fig. 6.

Structure shown in Figure 23 can comprise multiple unit, such as unit 1011 and unit 1012.Each unit can comprise identification massaging device as shown in Figure 6 or its part.Such as, unit 1011 is the structure shown in Fig. 6; And unit 1012 is a part for structure shown in Fig. 6, namely remove the 4th electrode 4 and contact 23 in structure shown in Fig. 6.Can electric connection or electric isolution between multiple unit, as shown in figure 23.

Multiple unit can be used for the part according to the corresponding coding of formula S n=Kn*Ra/Rb or a coding, and wherein Ra and Rb is that different electrical parameter that in multiple unit, same unit is determined or different units combine the different electrical parameters determined.Or Ra can be the electrical parameter that in multiple unit, one or more unit is determined, and Rb also can be another separate electrical parameter.Kn is coefficient, and Sn changes, see Fig. 6 along with the position difference of the first fracture.Electrical parameter and another separate electrical parameter can comprise resistance, voltage and current.

As shown in fig. 21-22, the first sub-electric resistance structure 411, comprises at least one resistance 3a, the 4th electrode 4 is connected to N+1 of the first electrode 1 part at least one of them.Second sub-electric resistance structure 560, comprises at least one resistive element 711 or resistive element 711 and electric resistance structure 511 (electric resistance structure 511 comprises at least one resistive element 3c), the 5th electrode 5 is connected at least part of second electrode 2.

As shown in fig. 21-22, the 3rd sub-electric resistance structure 611 comprises at least one resistance 3b, and the 6th electrode 6 is connected to one of at least part of second electrode 2 or N+1 part 111,112 and 113.

The sub-electric resistance structure 560 of first sub-electric resistance structure 411, second, the 3rd sub-electric resistance structure 611 can be used for the structure expanding above-mentioned each electric resistance structure and identification massaging device, and determine various electrical parameter and electrical parameter ratio by different contact combinations, as shown in figures 21-23, but be not limited thereto.

As shown in figure 23, the another kind of modification of electric resistance structure can comprise the first electric resistance structure 1011, second electric resistance structure 1012, the first contact 21 be connected with the first electric resistance structure, the 5th contact 25 be connected with the second electric resistance structure, the 3rd contact 23 be connected with the first electric resistance structure, the 6th contact 26 that is connected with the second electric resistance structure.First electric resistance structure 1011 and the second electric resistance structure 1012 can be independently electric resistance structures, also can be the electric resistance structures of association.

First electric resistance structure 1011 can comprise: the first electrode 1; Second electrode 2; Multiple first resistive element 3, each first resistive element 3 one end is connected to the first electrode 1 and the other end is connected to the second electrode 2; At least one fracture 11 and 12, first electrode 1 is divided at least two parts 111,112 and 113 by least one fracture 11 and 12, and at least one fracture 11 and 12 is each between adjacent two the first resistive elements 3 or disconnect the connection of at least one first resistive element 3 and the first electrode 1.

There is between first contact 21 and the 3rd contact 23 first electrical parameter R1, there is between the 5th contact 25 and the 6th contact 26 second electrical parameter R2.Electric resistance structure be configured so that the first electrical parameter R1 along with at least one fracture 11 and 12 at least the position of one of them difference and change.

According to some embodiments, the second electric resistance structure can comprise at least part of first electric resistance structure, as shown in figures 21-23.

According to some embodiments, one of the 5th contact 25 and the 6th contact 26 can be shared same contacts with one of the first contact 21 and the 3rd contact 23.That is, as shown in fig. 21-22, the first electric resistance structure is connected with the second electric resistance structure, and the first contact 21 can simultaneously as the contact coordinated with the 3rd contact 23 and the 6th contact 26.Now, the 5th contact 25 can be omitted.

According to some embodiments, electric resistance structure can be configured to make the second electrical parameter R2 along with at least one fracture 11 and 12 at least the position of one of them difference and change.

According to some embodiments, the second electric resistance structure can comprise: the second electrode 2; 6th electrode 6; Multiple second resistive element 3b, each second resistive element 3b one end is connected to the second electrode 2 and the other end is connected to the 6th electrode 6.At least one of them has at least one second fracture 13 and makes the second electrode 2 or/and the 6th electrode 6 is divided at least two parts for second electrode 2 and the 6th electrode 6, and at least one second fracture 11 and 12 is each between adjacent two the first resistive elements 3 or disconnect the connection of at least one first resistive element 3 and the second electrode 2 or the 6th electrode 6.

The configuration of the second electric resistance structure can be similar with the first electric resistance structure.The structure of the first electric resistance structure and the second electric resistance structure is not limited to the example illustrated, can be any structure according to disclosure instruction.The configuration of the second electric resistance structure can comprise any resistive element, includes but not limited to shown by Figure 21-23.

Identification massaging device can comprise above-mentioned electric resistance structure.First electrical parameter R1 and the second electrical parameter R2 can according to a part for the corresponding coding of formula S n=Kn*Ra/Rb or a coding, and wherein Sn is a part for coding or coding, Ra to be one of R1 and R2, Rb be in R1 and R2 another, Kn is coefficient.According to some embodiments, Kn is relevant to manufacturing process.

In aforementioned arbitrary structures, the resistance of multiple first resistive element 3 can be mutually the same.

In aforementioned arbitrary structures, the resistance of multiple first resistive element 3 can be different from each other at least partly.

In aforementioned arbitrary structures, the first electrode 1 can be different from the material of the first resistive element 3 with the material of the second electrode 2.

In aforementioned arbitrary structures, the resistance of the first electrode 1 and the resistance of the second electrode 2 all can be less than the resistance of each first resistive element 3.

In aforementioned arbitrary structures, the first electrode 1 and the second electrode 2 can comprise silver, and multiple first resistive element 3 can comprise graphite.

In aforementioned arbitrary structures, second electrode 2 also can have M the second fracture 13, M be greater than 0 natural number, M the second fracture 13 is each between adjacent two the first resistive elements 3 or disconnect the connection of at least one first resistive element 3 and the second electrode 2.

In aforementioned arbitrary structures, multiple first resistive element 3 can be mutually the same.Its material and size can be mutually the same.

In aforementioned arbitrary structures, multiple first resistive element 3 can comprise the multiple resistor stripes be set parallel to each other.

In aforementioned arbitrary structures, multiple first resistive element 3 can comprise at least two resistor discs.

In aforementioned arbitrary structures, the material of multiple first resistive element 3 of part can be different from the material of other the first resistive elements 3.

In aforementioned arbitrary structures, the size of multiple first resistive element 3 of part can be different from the size of other the first resistive elements 3.

In aforementioned arbitrary structures, fracture is formed by cut or mechanical punching mode.

The embodiment of biology sensor

Figure 10 is a kind of schematic diagram of biology sensor body of detect analytes.Biology sensor body 9 can in conjunction with above-mentioned identification massaging device 1, to form biology sensor.As shown in Figure 10, biology sensor body 9 comprises a working electrode 92 and one to electrode 93, and for arranging the insulative substrate 93 of two test electrodes, working electrode 92 and be provided with reaction reagent layer on electrode 93 at least one of them.

Figure 11 demonstrates the schematic diagram of the biology sensor according to the first of disclosure embodiment with identification massaging device.Wherein, as shown in figure 11, identification massaging device 1 is positioned at the back side of biology sensor body 9, and by insulated substrate 93 and working electrode 92 and one to electrode 93 electrical isolation.The three-decker that goes up most wherein on Figure 11 is respectively responding layer, channel layer, upper cap rock.

Figure 12 demonstrates the schematic diagram of the biology sensor according to the second of disclosure embodiment with identification massaging device.Wherein recognize that massaging device 1 is positioned at the front of biology sensor body 9, and isolate with working electrode 92 with to electrode 93.

Figure 13 demonstrates the schematic diagram of the biology sensor according to the third of disclosure embodiment with identification massaging device.Wherein recognize that massaging device 1 is positioned at the front of biology sensor body 9, and with working electrode 92 and adjacent to electrode 93.Identification massaging device 1 is connected with biology sensor can saves space to electrode 93.And electrical isolation can make Instrument Design simple, therefore those skilled in the art can select as required.

Figure 24 schematically shows the STRUCTURE DECOMPOSITION figure of the biology sensor according to some Example embodiments of the disclosure.

See Figure 24, comprise insulativity substrate 91, functional electrode and identification massaging device 2409, insulation course 2407, reaction reagent layer 2405, channel layer 2403, upper cap rock 2401 according to the biology sensor 2400 of some Example embodiments of the disclosure.

Insulativity substrate 91 can be such as insulation sheet material, its tool electrical insulating property.Material for insulativity substrate 91 can include but not limited to: the Ins. ulative material such as polyethylene terephthalate, tygon, polystyrene, polyester, polypropylene, polycarbonate, Polyvinylchloride, resin, pottery.

Functional electrode and identification massaging device 2409 can comprise foregoing working electrode 92 and to electrode 93 and identification massaging device.Working electrode 92 and to electrode 93 as functional electrode.Functional electrode is not limited to working electrode and to electrode, can increases other electrodes according to practical application.

Identification massaging device and functional electrode can be positioned at the similar face of insulativity base plate 91.Now, recognize that massaging device can be connected with working electrode 92 with to electrode 93 electrical isolation or with working electrode 92 with to one of electrode 93.In addition, although Figure 24 illustrates that identification massaging device and functional electrode are positioned at the similar face of insulativity base plate 91, the disclosure is not limited thereto.Such as, recognize that massaging device and functional electrode can be positioned at the different surfaces of described insulativity base plate 91.

Material for functional electrode can be any suitable conductive material, includes but not limited to: the potpourri of carbon, silver or silver chloride, palladium, gold, platinum and other suitable conductive materials or conductive materials or its combination.Such as, can adopt graphite with the electrode of reaction reagent contact jaw, the part that the rear end of this electrode contacts with detecting instrument can adopt ag material.

Identification massaging device can be foregoing any one identification massaging device or its modification.Identification massaging device can comprise any one electric resistance structure foregoing or its modification.Identification massaging device can be resistor stripe for resistive element, also can selection standard resistor disc.

Insulation course 2407 comprises a perforate, with exposed portion working electrode with to electrode.The material of insulation course can include but not limited to heated drying type dielectric ink or uv-curing type dielectric ink, insulating tape etc.

Reaction reagent layer 2405 is placed in the perforate of drain insulating layer, and it contains the reagent identifying biological specimen, different along with detection sample difference.Such as, the reaction reagent of electrochemica biological sensor comprises oxidoreducing enzyme and electron mediator, after itself and sample react, produces electric signal.

Passage when channel layer 2403 is sample feedings, works with the pore one of upper cap rock.Sample is by the effect admission passage of capillary attraction.In the process entered, the air of Channel front end is discharged by pore, makes sample feeding smooth.The material of channel layer includes but not limited to double faced adhesive tape.

Upper cap rock 2401 comprises a pore, and it is positioned at the top of passage away from inlet end of channel layer.The lower surface of upper cap rock can be coated with water wetted material.Pore and water wetted material can strengthen the capillary action of passage.The material of upper cap rock is transparent or semitransparent, whether to facilitate observing response district sample introduction.

According to the difference identification information that identification infosystem is carried, detection system can select corresponding technical parameter, finally show that the analysis quality testing survey of which kind of type is carried out in testing result or judgement.

Electrical parameter described in the disclosure is not limited to resistance, can also comprise electric current, voltage etc.

More than specifically describe structure and the structure of identification massaging device of the present disclosure and biology sensor, from the foregoing, the disclosure, compared to existing design, has and reduces cost, reduce processed complex degree and be easy to the effect of extend information.

It should be noted that the biology sensor described in the disclosure is not limited to above-mentioned cited figure example with the correction parameter production method of identification massaging device, also comprise the various schemes used designed by disclosure principle spirit.

Such as, can united application according to electric resistance structure of the present disclosure, this electric resistance structure can comprise: the first electrode; Second electrode; Multiple first resistive element, first resistive element one end described in each is connected to described first electrode and the other end is connected to described second electrode; First fracture, described first electrode is divided into Part I and Part II by described first fracture, and described first fracture is between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode.Easy to understand, not departing under spirit of the present disclosure and instruction, by united application according to electric resistance structure of the present disclosure, can obtain multiple identification massaging device.Described multiple identification massaging device can have different encoding schemes.Above-mentioned electric resistance structure also can be applicable to other occasions, instead of is limited to embodiment of the present disclosure.

Above-mentioned electric resistance structure also can comprise: the 4th electrode, and described 4th electrode is connected with the described Part I of described first electrode; First contact, is connected with the described Part II of described first electrode; Second contact, with described second Electrode connection; And the 3rd contact, with described 4th Electrode connection.

The described Part II of above-mentioned first electrode also can have N number of second fracture, N be greater than 0 natural number, described N number of second fracture is each between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode, and described Part I is divided into N+1 part by described N number of second fracture.

Above-mentioned second electrode (2) also can have M the 3rd fracture, M be greater than 0 natural number, described M the 3rd fracture is each between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described second electrode, and described second electrode is divided into M+1 part by individual 3rd fracture of described M.

Above-mentioned electric resistance structure also can comprise: the 4th electrode; Multiple 5th electrode, the 5th electrode one end described in each is connected to described second electrode or described first electrode and the other end is connected to described 4th electrode.Described second electrode and described 4th electrode one of at least on can have multiple first fracture, described multiple first fracture is each between adjacent two the first resistive elements or the 5th electrode or disconnect the connection of at least one first resistive element or the 5th electrode and described second electrode.

According to some embodiments, identification massaging device comprises one of above-mentioned electric resistance structure, and wherein at least part of above-mentioned multiple first resistive element has rectilinear form.

According to another embodiment, identification massaging device comprises one of above-mentioned electric resistance structure, and wherein at least part of above-mentioned multiple first resistive element has curved shape, such as zigzag fashion.

According to some embodiments, biology sensor comprises one of above-mentioned identification massaging device.Identification massaging device and described working electrode 92 and electrode 93 is positioned to the similar face of described insulativity base plate 91, described identification massaging device and described working electrode 92 and to electrode 93 electrical isolation or with described working electrode 92 be connected one of electrode 93.Described identification massaging device and described working electrode 92 and electrode 93 is positioned to the different surfaces of described insulativity base plate 91.

According to some embodiments, a kind of electric resistance structure unit can be provided.Electric resistance structure unit can comprise any one electric resistance structure aforesaid.Described electric resistance structure unit can be used for identification massaging device or other devices.

According to some embodiments, a kind of identification message unit can be provided.Identification message unit can comprise any one electric resistance structure aforesaid.Described identification message unit can be used for identification massaging device or other devices.

According to some embodiments, described identification massaging device determines identification information for utilizing the ratio of electrical parameter and one second electrical parameter characterized by described electric resistance structure.

According to some embodiments, described second electrical parameter comprises resistance, voltage or electric current.

According to some embodiments, described second electrical parameter associates with described electric resistance structure or has nothing to do.

According to some embodiments, described second electrical parameter is from testing tool.

Easy to understand, is not limited to be applied to biology sensor according to electric resistance structure of the present disclosure or electric resistance structure unit, and it also can be applied in other suitable systems.Also be not limited to be applied to biology sensor according to identification message unit of the present disclosure or identification massaging device, it also can be applied in other suitable systems.

In the determination methods of the identification massaging device described in the disclosure, electrode can use carbon, silver etc. to have the material of electric conductivity, and the method such as serigraphy, plating can be adopted to be fabricated on insulating base.

To utilize serigraphy manufacture to recognize, the method for massaging device is described below, the method comprises the screen mesh printing plate making and preset electrode shape, utilizes described screen mesh printing plate that print conductive materials is formed corresponding electrode at insulating base.Fracture site can be set in advance on screen mesh printing plate, also after formation electrode system, can form fracture by the method such as cut or mechanical punching.To recognize that massaging device 1 is positioned at the front of biology sensor body 9, first complete the production of whole test-paper, then test-paper test is carried out, select the technical parameter that this batch suitable, the fracture site corresponding according to suitable technical parameter, adopt modes such as swashing sheet cutting or punching to form fracture, thus the identification massaging device completing this batch of test-paper is produced.

Owing to recognizing that the electrode of massaging device is made up of conductive material, if outside being directly exposed to by these electrodes, the material in environment can stick on electrode, change the actual electrical parameters of electrode, cause and detect the inaccurate of data.Therefore, the disclosure covers a layer insulating on the electrode of identification massaging device, and described insulation course can be the weak material of the electric conductivities such as adhesive sticker, plastic sheet or UV cured printing ink.

The measurable analysis thing of the biology sensor of identifying information device of the present disclosure is used to comprise as the alcohol in the body fluid such as whole blood, urine, saliva, glucose, uric acid, lactate, cholesterol, cholerythrin, haemoglobin, glutamic-pyruvic transaminase etc.

Although exemplary embodiment describe the disclosure with reference to several, should be appreciated that term used illustrates and exemplary and nonrestrictive term.Specifically can implement in a variety of forms due to the disclosure and not depart from spirit of the present disclosure or essence, so be to be understood that, above-described embodiment is not limited to any aforesaid details, and should explain widely in the spirit and scope that claims limit, therefore fall into whole change in claim or its equivalent scope and remodeling and all should be claims and contained.

Claims (17)

1. an electric resistance structure, is characterized in that, comprising:

First electrode;

Second electrode;

Multiple first resistive element, first resistive element one end described in each is connected to described first electrode and the other end is connected to described second electrode;

First fracture, described first electrode is divided into Part I and Part II by described first fracture, and described first fracture is between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode.

2. electric resistance structure as claimed in claim 1, is characterized in that, also comprise;

4th electrode, described 4th electrode is connected with the described Part I of described first electrode;

First contact, is connected with the described Part II of described first electrode;

Second contact, with described second Electrode connection; And

3rd contact, with described 4th Electrode connection.

3. electric resistance structure as claimed in claim 1 or 2, it is characterized in that, the described Part II of described first electrode also has N number of second fracture, N be greater than 0 natural number, described N number of second fracture is each between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described first electrode, and described Part I is divided into N+1 part by described N number of second fracture.

4. electric resistance structure as claimed in claim 1 or 2, it is characterized in that, described second electrode also have M the 3rd fracture, M be greater than 0 natural number, described M the 3rd fracture is each between adjacent two the first resistive elements or disconnect the connection of at least one first resistive element and described second electrode, and described second electrode is divided into M+1 part by individual 3rd fracture of described M.

5. electric resistance structure as claimed in claim 1 or 2, is characterized in that, also comprise:

4th electrode;

Multiple second resistive element, second resistive element one end described in each is connected to described second electrode or described first electrode and the other end is connected to described 4th electrode.

6. electric resistance structure as claimed in claim 5, is characterized in that:

Wherein said second electrode and described 4th electrode one of at least on there is multiple first fracture, described multiple first fracture is each between adjacent two the first resistive elements or the second resistive element or disconnect the connection of at least one first resistive element or the second resistive element and described second electrode.

7. electric resistance structure as claimed in claim 5, is characterized in that:

Described multiple first resistive element and described multiple second resistive element are symmetrical arranged.

8. electric resistance structure as claimed in claim 7, is characterized in that:

Corresponding first resistive element and the second resistive element form as one.

9. electric resistance structure as claimed in claim 1 or 2, it is characterized in that, described multiple first resistive element is mutually the same.

10. electric resistance structure as claimed in claim 1 or 2, it is characterized in that, described multiple first resistive element comprises the multiple resistor stripes be set parallel to each other.

11. electric resistance structures as claimed in claim 1 or 2, is characterized in that, described multiple first resistive element comprises at least two resistor discs.

12. electric resistance structures as claimed in claim 1 or 2, is characterized in that, the size of described multiple first resistive element of part is different from the size of other the first resistive elements.

13. 1 kinds of identification massaging devices, is characterized in that, comprising:

Electric resistance structure according to any one of claim 1-12,

Wherein at least part of described multiple first resistive element has curved shape.

14. 1 kinds of identification massaging devices, is characterized in that, comprising:

Electric resistance structure according to any one of claim 1-12,

Wherein at least part of described multiple first resistive element has rectilinear form.

15. 1 kinds of biology sensors, is characterized in that, comprising:

Biology sensor body, comprises and is arranged on working electrode on insulativity base plate and to electrode, is at least provided with reaction reagent layer at working electrode with on one of electrode; And

Identification massaging device as described in claim 13 or 14, is positioned on described insulativity base plate.

16. biology sensors as claimed in claim 15, it is characterized in that, described identification massaging device and described working electrode and electrode is positioned to the similar face of described insulativity base plate, described identification massaging device and described working electrode and to electrode electrical isolation or with described working electrode be connected one of electrode.

17. biology sensors as claimed in claim 15, is characterized in that, described identification massaging device and described working electrode and electrode is positioned to the different surfaces of described insulativity base plate.