KR102038085B1 - A sample measurement strip sensor having magnetically coupled structure and sample mixing device for facilitating connected of strip sensor using the same - Google Patents

Abstract

The present invention relates to a sample measurement strip sensor having a magnetic coupling structure, and more specifically, to a sample measurement strip sensor comprising: a sensor main body; a reaction container; a plurality of reagent containers; and a plurality of channels. Furthermore, the present invention is configured so as to allow the combination of a magnet of the sample measurement strip sensor and a magnetic member of a mixer to stay securely and strongly coupled, and thus can allow the liquid material of a reaction reagent to be reliably supplied to the reaction container in a fixed amount.

Description

A SAMPLE MEASUREMENT STRIP SENSOR HAVING MAGNETICALLY COUPLED STRUCTURE AND SAMPLE MIXING DEVICE FOR FACILITAITATING CONNECTED OF STRIP SENSOR USING THE SAME}

The present invention relates to a sample measuring strip sensor having a magnetic coupling structure and a sample mixing device for facilitating the coupling of the strip sensor using the same. More specifically, a magnet is attached to the sample measuring strip sensor, and the magnet is formed in the mixer. By forming a magnetic member corresponding to the magnetic coupling structure of the magnetic method to maintain the fastening state by being tightly adhered by the magnetic at the time of fastening the sample measuring strip sensor and the mixer to prevent leakage of air emitted from the mixer It relates to a sample measuring strip sensor having a and a sample mixing device to facilitate the coupling of the strip sensor using the same.

In general, in the case of a diagnostic sensor using a biochip, various various measurement methods such as an electrochemical measurement method, a potential difference measurement method, and a chemiluminescence method are used. In recent years, a chemiluminescence method for measuring a concentration of a desired substance by measuring the intensity of a signal (photoreaction) generated by injecting a sample and a reactant into a micro-induction channel using a microfluidic control device is performed. It is used a lot.

Chemiluminescent methods using such microfluidic control devices require complex systems when injecting or mixing fluids for accurate quantitation of samples or reagents. In particular, in the case of chemiluminescent biosensors, in order for a reaction to occur, a quantitative mixing ratio of a quantitative sample, a reaction medium, and a light emitter must be maintained. That is, in order to accurately measure the mixed reaction of the sample and the reactant, the quantitative sample is injected into the reaction part, and then the reactant or reagent reacting with the sample is quantitatively injected into the reaction part. Careful attention is required to inject the quantitatively into the solution, which causes a problem in that it takes a long time to quantitatively inject the reactant or reagent into the reaction unit.

Conventional sample mixers require the sample strip sensor and mixer to be in close contact with each other so that the air released from the mixer can be mixed by pushing the liquid reaction reagent material stored in the sensor through the sensor passage, but there is a gap between the sensor and the mixer. As air leaks through the outside, there is a problem that the quantitative reaction reagent material is difficult to mix. Republic of Korea Patent Publication No. 10-2013-0097073, Patent Publication No. 10-2014-0012579, and Patent No. 10-0901467 are disclosed in the prior art literature.

The present invention has been proposed to solve the above problems of the conventionally proposed methods, by forming a magnet attached to the sample measuring strip sensor, the magnetic member corresponding to the magnet is formed in the mixer, the sample measuring strip sensor To provide a sample mixing device for facilitating the combination of the strip measuring sensor and the sample measuring strip sensor having a magnetic coupling structure, which is strongly adhered by the magnetic when the mixer and the mixer is fastened to maintain a secure fastening state For that purpose.

In addition, the present invention is configured to maintain a tightly coupled state of tightly coupled by the combination of the magnet of the sample strip sensor and the magnetic member of the mixer, thereby injecting the liquid reaction reagent material stored in the reagent vessel into the reaction vessel Of the strip measuring sensor and the strip sensor having the magnetic coupling structure, which prevents the air emitted from the air from leaking to the outside, thereby allowing the liquid reaction reagent material to be quantitatively and stably supplied to the reaction vessel. Another object is to provide a sample mixing device that facilitates bonding.

Sample measuring strip sensor having a magnetic coupling structure according to a feature of the present invention for achieving the above object,

Sample measuring strip sensor with a magnetic coupling structure,

A rectangular body forming the overall appearance, the sensor body is formed with a magnet for coupling on the back;

A reaction vessel formed at a central portion of the sensor main body, supplied with a sample material supplied from the outside and stored therein, and mixed with a liquid reaction reagent material supplied to the stored sample material;

A plurality of reagent containers in which a liquid reaction reagent material supplied to the reaction container is stored, and supplying a liquid reaction reagent material to the reaction container by a pressing force of air discharged from the outside; And

The mixing vessel and the plurality of reagent vessels, characterized in that it comprises a plurality of channels for forming a passage for the liquid reaction reagent material supplied from the plurality of reagent vessels flow to the reaction vessel.

Preferably, the sensor body,

A vertical long groove may be formed on the rear surface of the sensor main body so that the magnet is attached.

More preferably, the magnet is,

It may be composed of a thin strip-shaped magnet having a shape and size corresponding to the vertical long groove to be coupled to the vertical long groove formed on the rear of the sensor body.

Preferably, the reaction vessel,

The sensor body may be integrally formed at a central portion of the sensor main body, and may be configured to have an elongated cylindrical shape forming an inlet of the upper opening.

More preferably, the plurality of reagent containers,

The reaction vessel may be sequentially arranged on both sides of the reaction vessel made of an elongated cylindrical shape forming an inlet of the upper opening.

Even more preferably, the plurality of reagent vessels,

It is formed in the interior of the sensor body in a sealed space sequentially arranged on both sides of the reaction vessel, each reagent vessel may further form an injection tube that is a passage through the rear of the sensor body.

Preferably, the plurality of channels,

The reaction vessel and the plurality of reagent vessels may be connected to each other, and the lower portion of each reagent vessel may be inclinedly connected to one side of the reaction vessel.

More preferably, the plurality of channels,

As an inclined passage connected obliquely from top to bottom, the connection portion of the plurality of reagent vessels may be configured in a structure of a downward inclined passage having a high connection portion of the reaction vessel is low.

More preferably, the plurality of channels,

Each channel is a passage having a small diameter, and the number of ray nozzles is small so that the viscous force is superior to the inertial force of the liquid reaction reagent material, thereby preventing the liquid reaction reagent material from naturally flowing into the reaction vessel through the inclined passage. Can be.

Sample mixing apparatus for facilitating the coupling of the sample measuring strip sensor having a magnetic coupling structure according to a feature of the present invention for achieving the above object,

A sample mixing device for facilitating the coupling of a sample measuring strip sensor having a magnetic coupling structure,

A rectangular body forming an overall shape, the sensor body is formed with a magnet for coupling on the back, and formed in the center portion of the sensor body, the sample material supplied from the outside is supplied and stored, the stored sample material The reaction vessel in which the supplied liquid reaction reagent material is mixed, and the liquid reaction reagent material supplied to the reaction container are stored, and supplying the liquid reaction reagent material to the reaction vessel by the pressure of the air discharged from the outside. A sample measurement comprising a plurality of reagent vessels, a plurality of channels connecting the mixing vessel and the plurality of reagent vessels, and a plurality of channels forming a passage through which the liquid reaction reagent material supplied from the plurality of reagent vessels flows to the reaction vessel. Strip sensor; And

It is characterized in that it comprises a mixer that can be inserted and detachably detachable with the sample strip strip sensor, and a magnetically coupled magnetically and magnetically formed on the sensor body of the sample strip strip sensor.

Preferably, the mixer,

A sensor mounting part formed on a front surface of the mixer main body in a shape corresponding to the shape and size of the sensor main body so that the sample measuring strip sensor can be inserted and fastened;

A magnetic member formed to correspond to the magnet so as to be in close contact with the magnet of the sensor main body on an inner surface of the sensor mounting part; And

And a plurality of air injecting parts inserted into and fastened to the sensor mounting part and releasing air to a plurality of reagent containers of the sample strip sensor that are tightly coupled through the magnetic member.

More preferably, the magnetic member,

It may be composed of a magnet member formed corresponding to the shape and size of the magnet is formed attached to the sensor body.

More preferably, the magnetic member,

It may be composed of an iron member formed corresponding to the shape and size of the magnet is formed attached to the sensor body.

More preferably, the magnetic member,

An injection tube formed of a magnet member or an iron member, each of which is formed in a plurality of reagent containers when the sensor main body of the sample strip sensor is inserted into the sensor mounting part and tightly coupled to the magnet of the sensor main body. Each of the corresponding air inlets may function to be in tight contact with no air leaks.

Preferably, the mixer,

A cover inserted and fastened to the sensor mounting part and covering and covering an upper portion of the sensor main body of the sample strip sensor that is tightly coupled by the magnetic member; And

It may further comprise a guide guide groove formed to guide the easy fastening when the sensor body of the sample measuring strip sensor is inserted into the sensor mounting portion to both sides of the sensor mounting portion.

More preferably, the sensor body,

A vertical long groove is formed on the rear surface of the sensor main body so that the magnet can be attached, and the magnet is formed of a thin band-shaped magnet having a shape and size corresponding to the vertical long groove. It may be configured to have a fastening structure coupled to the long groove.

More preferably, the reaction vessel,

The sensor body may be integrally formed at a central portion of the sensor main body, and may be configured to have an elongated cylindrical shape forming an inlet of the upper opening.

Even more preferably, the plurality of reagent vessels,

The reaction vessel may be sequentially arranged on both sides of the reaction vessel made of an elongated cylindrical shape forming an inlet of the upper opening.

Even more preferably, the plurality of reagent vessels,

An injection tube, which is a passage that penetrates the rear surface of the sensor main body, may be in close contact with the air injection portion, thereby eliminating gaps between corresponding connection portions.

More preferably, the plurality of channels,

The reaction vessel and the plurality of reagent vessels may be connected to each other, and the lower portion of each reagent vessel and one side of the reaction vessel may be inclined downwardly.

According to the present invention, a sample measuring strip sensor having a magnetic coupling structure and a sample mixing device for facilitating the coupling of the strip sensor using the same, the magnet is attached to the sample measuring strip sensor, corresponding to the magnet in the mixer By configuring the magnetic member to be formed, it is possible to maintain a strong fastening state by being closely adhered by the magnet at the time of fastening the sample measuring strip sensor and the mixer.

In addition, according to the sampling strip sensor having a magnetic coupling structure proposed in the present invention and the sample mixing device for facilitating the coupling of the strip sensor using the same, by combining the magnet of the sample measuring strip sensor and the magnetic member of the mixer By maintaining a tightly held tightly coupled state, air from the mixer is prevented from leaking to the outside to inject the liquid reaction reagent material stored in the reagent vessel into the reaction vessel, and thus the liquid reaction reagent material is prevented. It can be supplied to the reaction vessel quantitatively and stably.

1 is a block diagram showing the configuration of a sample measuring strip sensor having a magnetic coupling structure according to an embodiment of the present invention as a functional block.
Figure 2 is a diagram showing a perspective view of the sample strip sensor having a coupling structure of the magnet method according to an embodiment of the present invention.
3 is a perspective view illustrating a process of attaching a magnet of a sample strip sensor having a magnetic coupling structure according to an embodiment of the present invention to a vertical long groove;
4 is a front view configuration of a sample strip sensor having a coupling structure of a magnet method according to an embodiment of the present invention.
5 is a plan view showing a sample measuring strip sensor having a magnetic coupling structure according to an embodiment of the present invention.
Figure 6 is a schematic diagram showing the overall configuration of the sample mixing device to facilitate the coupling of the sample measuring strip sensor having a magnetic coupling structure in accordance with an embodiment of the present invention.
7 is a block diagram showing the configuration of a mixer applied to the sample mixing device for facilitating the coupling of the sample measuring strip sensor having a magnetic coupling structure according to an embodiment of the present invention.
8 is a diagram illustrating a perspective view of a main part of a mixer applied to a sample mixing device for facilitating coupling of a sample measuring strip sensor having a magnetic coupling structure according to an embodiment of the present invention;
FIG. 9 is a view illustrating a fastening process of a sample measuring strip sensor and a mixer of a sample mixing device to facilitate coupling of a sample measuring strip sensor having a magnetic coupling structure according to an embodiment of the present invention; FIG.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. However, in describing the preferred embodiment of the present invention in detail, if it is determined that the detailed description of the related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. In addition, the same reference numerals are used throughout the drawings for parts having similar functions and functions.

In addition, in the specification, when a part is 'connected' to another part, it is not only 'directly connected' but also 'indirectly connected' with another element in between. Include. In addition, the term 'comprising' of an element means that the element may further include other elements, not to exclude other elements unless specifically stated otherwise.

1 is a block diagram showing the configuration of a sample measuring strip sensor having a magnetic coupling structure according to an embodiment of the present invention as a functional block, Figure 2 is a coupling structure of a magnet method according to an embodiment of the present invention FIG. 3 is a diagram illustrating a perspective view of a sample strip sensor having a perspective view, and FIG. 3 is a perspective view illustrating a process of attaching a magnet of a sample strip strip sensor having a magnetic coupling structure according to an embodiment of the present invention to a vertical long groove 4 is a view showing a front view configuration of a sample measuring strip sensor having a coupling structure of the magnet method according to an embodiment of the present invention, Figure 5 is a magnet method according to an embodiment of the present invention The top view of the sample strip sensor with a coupling structure is shown. As shown in FIGS. 1 to 5, the sample measuring strip sensor 100 having a magnetic coupling structure according to an embodiment of the present invention includes a sensor main body 110, a reaction vessel 120, and a plurality of sensors. It may comprise a reagent vessel 130, and a plurality of channels 140.

The sensor main body 110 is a rectangular body forming an overall appearance, and is a configuration of a main body in which a magnet 111 for coupling is formed on a rear surface thereof. As illustrated in FIG. 3, the sensor main body 110 may form a vertical long groove 112 on the rear surface of the sensor main body 110 so that the magnet 111 may be attached. At this time, the magnet 111 is to be composed of a thin band-shaped magnet having a shape and size corresponding to the vertical long groove 112 to be coupled to the vertical long groove 112 formed on the rear of the sensor body 110. Can be. Here, the vertical long groove 112 can be understood as the configuration of the groove for the magnetic defect.

The reaction vessel 120 is formed at a central portion of the sensor main body 110, and is a configuration of a vessel in which a sample material supplied from the outside is supplied and stored, and a liquid reaction reagent material supplied to the stored sample material is mixed. . The reaction vessel 120 may be integrally formed at the central portion of the sensor body 110, but may be configured in an elongated cylindrical shape to form an inlet 121 of the upper opening.

The plurality of reagent containers 130, the container for storing the liquid reaction reagent material supplied to the reaction vessel 120, the container for supplying the liquid reaction reagent material to the reaction vessel 120 by the pressure of the air discharged from the outside It is the composition. The plurality of reagent vessels 130 may be alternately arranged on both sides of the reaction vessel 120 having a long cylindrical shape forming the inlet 121 of the upper opening.

In addition, the plurality of reagent vessels 130 are formed inside the sensor body 110 as a sealed space that is sequentially arranged on both sides of the reaction vessel 120, each reagent vessel 130 is a sensor body 110 Injection tube 131 which is a passage penetrated to the rear of the) may be further formed.

The plurality of channels 140 connect the mixing vessel 120 and the plurality of reagent vessels 130, and a passage through which the liquid reaction reagent material supplied from the plurality of reagent vessels 130 flows to the reaction vessel 120. To form. The plurality of channels 140 may connect the reaction vessel 120 and the plurality of reagent vessels 130, respectively, and may obliquely connect the lower side of each reagent vessel 130 and one side of the reaction vessel 120.

In addition, the plurality of channels 140 are inclined passages connected obliquely from top to bottom, and have a structure of a downwardly inclined passage having a high connection portion of the plurality of reagent vessels 130 and a low connection portion of the reaction vessel 120. Can be configured.

In addition, the plurality of channels 140 are passages each channel 140 has a small diameter, the number of Reynolds is small, the viscous force is superior to the inertial force of the liquid reaction reagent material, the liquid reaction reagent material is natural through the inclined passage As such, it may function to prevent flow to the reaction vessel 120.

6 is a view schematically showing the entire configuration of a sample mixing device for facilitating the coupling of the sample measuring strip sensor having a magnetic coupling structure according to an embodiment of the present invention, Figure 7 is an embodiment of the present invention 8 is a view showing the configuration of a mixer applied to a sample mixing device for facilitating coupling of a sample measuring strip sensor having a magnetic coupling structure according to an example as a functional block, and FIG. 8 is a magnet according to an embodiment of the present invention. 9 illustrates a perspective view of a main part of a mixer applied to a sample mixing device for facilitating coupling of a sample strip sensor having a coupling structure of a method, and FIG. 9 illustrates a coupling structure of a magnet method according to an embodiment of the present invention. A diagram illustrating a fastening process of a sample measuring strip sensor and a mixer of a sample mixing device that facilitates coupling of a sample measuring strip sensor. 6 to 9, the sample mixing device 10 for facilitating the coupling of the sample measuring strip sensor having a magnetic coupling structure according to an embodiment of the present invention, the sample measuring strip sensor ( 100), and a mixer 200. Here, the specific configuration of the sample measuring strip sensor 100 is based on the configuration shown in Figs. 1 to 5, respectively.

The sample measuring strip sensor 100 is a rectangular body forming an overall appearance, and is formed at a sensor main body 110 having a magnet 111 for coupling to a rear surface thereof, and a central portion of the sensor main body 110. The sample material supplied from the outside is stored and stored, and the reaction vessel 120 in which the liquid reaction reagent material is supplied to the stored sample material is mixed, and the liquid reaction reagent material supplied to the reaction vessel 120 is stored. Connecting a plurality of reagent vessels 130 for supplying a liquid reaction reagent material to the reaction vessel 120 by the pressure of the air discharged from the outside, the mixing vessel 120 and the plurality of reagent vessels 130, A plurality of channels 140 may be provided to form a passage through which the liquid reaction reagent material supplied from the plurality of reagent vessels 130 flows to the reaction vessel 120.

In addition, the sensor main body 110 of the sample measuring strip sensor 100, as shown in Figure 3, to form a vertical long groove 112 in the rear of the sensor main body 110 so that the magnet 111 is attached and formed; , The magnet 111 is a fastening structure that is composed of a thin strip-shaped magnet having a shape and size corresponding to the vertical long groove 112 is coupled to the vertical long groove 112 formed on the rear of the sensor body 110 is attached to Can be done.

In addition, the reaction vessel 120 of the sample strip sensor 100 may be integrally formed at the central portion of the sensor body 110, and may be configured to have a long cylindrical shape to form an inlet 121 of the upper opening.

In addition, the plurality of reagent vessels 130 of the sample strip sensor 100 may be alternately arranged on both sides of the reaction vessel 120 having a long cylindrical shape forming the inlet 121 of the upper opening. . Such a plurality of reagent containers 130 are strongly connected to the air inlet 230 of the mixer 200, which will be described later, the injection tube 131, which is a passage that passes through the rear surface of the sensor body 110, and corresponds to a corresponding connection site. It can be used to eliminate the gap between. Here, the injection tube 131 may be used as a passage through which a liquid reaction reagent material is supplied using a syringe, and a passage through which air discharged from the air injection unit 230 of the mixer 200 to be described later is injected.

In addition, the plurality of reagent vessels 130 may be a predetermined amount of the liquid reaction reagent material set by the pressure applied to the air discharged from the air inlet 230 of the mixer 200, which will be described later, to the reaction vessel 120. To be supplied. In addition, the plurality of reagent vessels 130 may be understood to be composed of a material having a different property, each of which stores the reaction reagent material in the liquid phase.

In addition, the plurality of channels 140 of the sample strip sensor 100 connect the reaction vessel 120 and the plurality of reagent vessels 130, respectively, the lower portion of each reagent vessel 130 and the reaction vessel 120. One side of the can be connected inclined downward.

In addition, the sample measuring strip sensor 100 may be implemented as a biosensor that functions as a sensor for diagnosing a chemiluminescence method.

The mixer 200 may be inserted into and detachably attached to the sample strip sensor 100, and may be magnetically coupled to the magnet 111 formed in the sensor body 110 of the sample strip strip 100 in close magnetic contact. Configuration of the device. The mixer 200 is a measuring device for detecting the characteristics appearing in the mixed material mixed with the sample material and the liquid reaction reagent material is supplied to the reaction vessel 120 of the sample strip sensor 100 by the chemiluminescence method It can be understood as the configuration of. Here, the mixer 200 describes a structure in which the mixer 200 is tightly coupled so that a gap does not occur in the connection portion between the sensor and the mixer when the coupling with the sample measuring strip sensor 100 is performed. Will be omitted.

The mixer 200 may include a sensor mounting unit 210, a magnetic member 220, and an air injection unit 230, as shown in FIGS. 7 to 9, respectively, and a lid 240. The guide guide groove 250 may be further included.

The sensor mounting unit 210 of the mixer 200 is configured to be formed on the front surface of the mixer body 201 in a shape corresponding to the shape and size of the sensor body 110 so that the sample measuring strip sensor 100 can be inserted and fastened. .

The magnetic member 220 of the mixer 200 is configured to correspond to the magnet 111 to be in close contact with the magnet 111 of the sensor body 110 to the inner surface of the sensor mounting portion 210. As shown in FIGS. 8 and 9, the magnetic member 220 may be configured as a magnet member formed corresponding to the shape and size of the magnet 111 formed by being attached to and attached to the sensor body 110. .

In addition, the magnetic member 220 may be formed of an iron member formed corresponding to the shape and size of the magnet 111 formed by being coupled to the sensor body 110.

In addition, the magnetic member 220 is composed of a magnetic member or an iron member, the sensor body 110 of the sample measuring strip sensor 100 is inserted and fastened to the sensor mounting portion 210, the magnet 111 of the sensor body 110 When tightly coupled to each other), each of the injection pipes 131 and the air inlet 120 corresponding to each of the injection tubes 131 formed in the plurality of reagent containers 130 functions to be in close contact with each other without air leakage.

The plurality of air inlets 230 of the mixer 200 are inserted into and fastened to the sensor mounting unit 210, and are connected to the plurality of reagent containers 130 of the sample measuring strip sensor 100 tightly coupled through the magnetic member 220. It is a structure for releasing air.

As shown in FIGS. 8 and 9, the cover 240 of the mixer 200 is inserted into and fastened to the sensor mounting unit 210, and the sample measuring strip sensor 100 is tightly coupled by the magnetic member 220. It is a configuration to cover the upper portion of the sensor body 110 of. The cover 240 may be moved along the guide rail fastened to both sides.

The guide guide groove 250 of the mixer 200 guides easy coupling when inserting and fastening the sensor body 110 of the sample strip sensor 100 to the sensor mounting unit 210 at both sides of the sensor mounting unit 210. It is formed for. The guide guide groove 250 may serve to provide a free space when the operator grips the small sample measuring strip sensor 100 by hand and inserts it into the sensor mounting unit 210 of the mixer 200.

As described above, the sample mixing strip sensor having a magnetic coupling structure according to an embodiment of the present invention and the sample mixing device for facilitating the coupling of the strip sensor using the same, the magnet is formed attached to the sample measuring strip sensor By forming a magnetic member corresponding to the magnet in the mixer, the magnetic stripe may be strongly adhered by magnetism when the sample strip sensor and the mixer are coupled to each other to maintain a firm coupling state. The combination of the magnet and the magnetic member of the mixer is configured to maintain a tightly held tightly coupled state, thereby preventing the air from the mixer from leaking out of the mixer to inject the liquid reaction reagent material stored in the reagent container into the reaction container. , The liquid reaction reagent material can be quantitatively and stably You can be urgent.

The present invention described above may be variously modified or applied by those skilled in the art, and the scope of the technical idea according to the present invention should be defined by the following claims.

10: sample mixing apparatus according to an embodiment of the present invention
100: sample strip sensor
110: sensor body
111: magnet
112: magnetic coupling groove
120: reaction vessel
121: entrance
130: reagent vessel
131: injection tube
140: channel
200: mixer
201: mixer body
210: sensor mounting portion
220: magnetic member
230: air injection unit
240: cover
250: guide guide groove

Claims (20)

As a sample measuring strip sensor 100 having a magnetic coupling structure,
A rectangular body forming the overall appearance, the sensor body 110 is formed with a magnet 111 for coupling on the back;
A reaction vessel 120 formed at a central portion of the sensor body 110 and supplied with a sample material supplied from the outside and stored therein, and mixed with a liquid reaction reagent material supplied to the stored sample material;
A plurality of reagent containers 130 for storing the liquid reaction reagent material supplied to the reaction vessel 120 and supplying the liquid reaction reagent material to the reaction vessel 120 by the pressing force of air discharged from the outside; And
A plurality of reaction vessels 120 and the plurality of reagent vessels 130 are connected to each other and form a passage through which the liquid reaction reagent material supplied from the plurality of reagent vessels 130 flows to the reaction vessel 120. Sampling strip sensor having a magnetic coupling structure, characterized in that it comprises a channel (140).
The method of claim 1, wherein the sensor body 110,
Sample measuring strip sensor having a magnetic coupling structure, characterized in that to form a vertical long groove 112 in the rear of the sensor body 110 so that the magnet 111 is attached.
The method of claim 2, wherein the magnet 111,
Characterized in that consisting of a thin strip-shaped magnet having a shape and size corresponding to the vertical long groove 112 to be coupled to the vertical long groove 112 formed on the rear of the sensor body 110, Sampling strip sensor with magnetic coupling structure.
The method of claim 1, wherein the reaction vessel 120,
Formed integrally at the central portion of the sensor body 110, characterized in that formed in a long cylindrical shape to form an inlet 121 of the upper opening, the sample measuring strip sensor having a magnetic coupling structure.
The method of claim 4, wherein the plurality of reagent vessels 130,
Sample measuring strip sensor having a coupling structure of the magnet type, characterized in that arranged alternately on both sides of the reaction vessel 120 made of a long cylindrical shape to form an inlet 121 of the upper opening.
The method of claim 5, wherein the plurality of reagent vessels 130,
Is formed in the interior of the sensor body 110 in a sealed space sequentially arranged on both sides of the reaction vessel 120, each reagent vessel 130 is a passage through the back of the sensor body 110 Sample measuring strip sensor having a magnetic coupling structure, characterized in that further forming a phosphorus injection tube (131).
The method according to any one of claims 1 to 6, wherein the plurality of channels 140,
The reaction vessel 120 and the plurality of reagent vessels 130 are connected, respectively, characterized in that the lower side of each of the reagent vessels 130 and one side of the reaction vessel 120 is inclinedly coupled, magnetic coupling Sample strip sensor with structure.
The method of claim 7, wherein the plurality of channels 140,
As an inclined passage connected obliquely from the top to the lower, characterized in that the connection portion of the plurality of reagent vessels 130, the connection portion of the reaction vessel 120 is characterized by consisting of a downwardly inclined passage structure, Sample measuring strip sensor with a magnetic coupling structure.
The method of claim 7, wherein the plurality of channels 140,
Each channel 140 is a passage having a small diameter, the number of Reynolds is small, the viscous force is superior to the inertial force of the liquid reaction reagent material, the liquid reaction reagent material naturally flows through the inclined passage to the reaction vessel 120 Sample measuring strip sensor having a magnetic coupling structure, characterized in that the function to be prevented from being.
A sample mixing device (10) for facilitating the coupling of a sample measuring strip sensor having a magnetic coupling structure,
A rectangular body forming an overall shape, the sensor body 110 is formed with a magnet 111 for coupling on the back, and formed in the center of the sensor body 110, the sample material supplied from the outside is supplied And the reaction container 120 in which the liquid reaction reagent material is mixed and stored in the stored sample material, and the liquid reaction reagent material supplied to the reaction container 120 is stored and discharged from the outside. A plurality of reagent vessels 130 for supplying a liquid reaction reagent material to the reaction vessel 120 by a pressing force, and connecting the reaction vessel 120 and the plurality of reagent vessels 130, and the plurality of reagent vessels A sample measuring strip sensor (100) having a plurality of channels (140) for forming a passage through which the liquid reaction reagent material supplied from (130) flows into the reaction vessel (120); And
The mixer 200 may be inserted into and detachably attached to the sample measuring strip sensor 100, and may be strongly and magnetically coupled to the magnet 111 formed on the sensor body 110 of the sample measuring strip sensor 100. Sample mixing apparatus for facilitating the coupling of the measuring strip sensor having a magnetic coupling structure, characterized in that it comprises a).
The method of claim 10, wherein the mixer 200,
A sensor mounting part 210 formed on a front surface of the mixer body 201 in a shape corresponding to the shape and size of the sensor body 110 so that the sample measuring strip sensor 100 can be inserted and fastened;
A magnetic member 220 formed to correspond to the magnet 111 to be in close contact with the magnet 111 of the sensor main body 110 on the inner surface of the sensor mounting part 210; And
A plurality of air injecting parts inserted into and fastened to the sensor mounting part 210 to discharge air to the plurality of reagent containers 130 of the sample strip sensor 100 tightly coupled through the magnetic member 220 ( And a sample mixing device for facilitating the coupling of the sample measuring strip sensor having a magnetic coupling structure.
The method of claim 11, wherein the magnetic member 220,
The combination of the sample measuring strip sensor having a magnetic coupling structure, characterized in that consisting of a magnet member formed corresponding to the shape and size of the magnet 111 is formed attached to the sensor main body 110 Sample mixing device to facilitate.
The method of claim 11, wherein the magnetic member 220,
The combination of the sample measuring strip sensor having a magnetic coupling structure, characterized in that consisting of an iron member formed corresponding to the shape and size of the magnet 111 is formed attached to the sensor main body 110 Sample mixing device to facilitate.
The method of claim 11, wherein the magnetic member 220,
Consists of a magnet member or an iron member, the sensor body 110 of the sample measuring strip sensor 100 is inserted and fastened to the sensor mounting portion 210, in close contact with the magnet 111 of the sensor body 110 is coupled When the injection tube 131 and the air inlet 120 corresponding to each of the plurality of reagent vessels 130 are formed so as to be in close contact with the air tightly, characterized in that the tightly coupled, the magnetic coupling A sample mixing device for facilitating the coupling of a sample measuring strip sensor having a structure.
The method according to any one of claims 11 to 14, wherein the mixer 200,
A cover 240 inserted and fastened to the sensor mounting unit 210 and covering and covering an upper portion of the sensor body 110 of the sample strip sensor 100 that is tightly coupled by the magnetic member 220; And
Guide guide grooves 250 formed to guide easy fastening when the sensor body 110 of the sample measuring strip sensor 100 is inserted into and fastened to the sensor mounting portion 210 on both sides of the sensor mounting portion 210. The sample mixing device to facilitate the coupling of the sample measuring strip sensor having a magnetic coupling structure, characterized in that it further comprises a.
The method of claim 15, wherein the sensor body 110,
The vertical long groove 112 is formed on the rear surface of the sensor body 110 so that the magnet 111 can be attached and formed, and the magnet 111 has a thin strip having a shape and size corresponding to the vertical long groove 112. Combination of the sample measuring strip sensor having a magnetic coupling structure, characterized in that it has a fastening structure that is coupled to the vertical long groove 112 formed in the rear of the sensor body 110 is formed of a magnet of the shape Sample mixing device to facilitate.
The method of claim 15, wherein the reaction vessel 120,
Formed integrally with the central portion of the sensor body 110, characterized in that formed in a long cylindrical shape to form the inlet 121 of the upper opening, the combination of the sample measuring strip sensor having a magnetic coupling structure Sample mixing device to facilitate.
The method of claim 17, wherein the plurality of reagent vessels 130,
The combination of the measuring strip sensor having a magnetic coupling structure, characterized in that arranged sequentially on both sides of the reaction vessel 120 made of a long cylindrical shape forming an inlet 121 of the upper opening. Sample mixing device to facilitate.
The method of claim 18, wherein the plurality of reagent vessels 130,
Injecting tube 131 which is a passage penetrating to the rear of the sensor body 110 is in close contact with the air inlet 230 to remove the gap of the corresponding connection portion, having a magnetic coupling structure Sample mixing device for facilitating the coupling of sample measuring strip sensors.
The method of claim 15, wherein the plurality of channels 140,
The reaction vessel 120 and the plurality of reagent vessels 130 are connected, respectively, characterized in that the lower side of each of the reagent vessels 130 and one side of the reaction vessel 120 is inclined downwardly connected, A sample mixing device for facilitating the coupling of a sample measuring strip sensor having a coupling structure.

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