KR102009116B1 - Test strip - Google Patents

Abstract

The present invention relates to a test strip, the test strip according to an embodiment of the present invention is formed into a plate shape having a predetermined length, the test sheet 10, one end 11 is immersed in the test liquid 1, the test The reagent pad 20, which is disposed on one surface of the sheet 10, and is discolored in response to the test liquid 1, is disposed on the test sheet 10 along the longitudinal direction of the test sheet 10. The inspection corresponding to the moving distance of the flow part 30 which moves the test liquid 1 absorbed at one end to the other end direction, and the test liquid 1 which moves along the flow part 30 when 10 is immersed. And a time scale unit 40 for displaying the time.

Description

Test strip {TEST STRIP}

The present invention relates to a test strip.

In the case of a patient's visit, the doctor diagnoses the patient as a precondition of treatment and diagnoses the patient by various medical examination methods to examine the symptoms. At this time, the usual medical examination methods include a questionnaire asking the patient directly about the medical history and the time of invention, a tasting patting the patient's body, facilitating the diagnosis by touching the patient's body, and a visual examination of the condition with the naked eye, within the patient's body. I have a stethoscope to diagnose sounds. In addition to these examination methods, blood tests or urine tests are performed to more accurately determine the type of disease. Urine is a waste product after filtering blood from the kidney and contains various metabolites. Thus, urine tests can be used to obtain information about urinary system abnormalities as well as systemic endocrine and metabolic diseases. In addition, the urine can be collected in a non-invasive manner without burdening the patient compared to the blood collection, urine test is very useful in the medical field. The urine test examines physical properties such as color and turbidity of urine, and semi-politically detects various kinds of wastes discharged from urine. At this time, color tone and turbidity are visually inspected, smell is sensed by smell, and red blood cells, white blood cells, bacteria and various crystals are observed using a microscope. In addition, a chemical test using urine strips (urine strip) is also performed, through which urine protein, urine sugar, hematuria, etc. can be easily examined.

Urine analysis device using such a urine test rod is disclosed in the patent document of the following prior art document. Conventional urine test rods are prepared in advance for the reaction unit for a number of items, the urine test rods are immersed in the urine and the disease is read through the color change of the reaction unit at a point in time after a predetermined test time. At this time, the reading of the disease visually contrasts the color table and color provided by the manufacturer, or uses a dedicated reading machine.

In the inspection using a conventional urine test rod, the most important point is to accurately observe the inspection time. At this time, the most important point is to observe the inspection time accurately. This is because the color of the reaction part continuously changes according to the test time, and the disease cannot be accurately read unless the test time is strictly observed. In the general medical field using the urine test rods, a separate timer is used to check the test time. At this time, if the examiner does not pay attention even for a while, the test time is easily missed. Therefore, the inspector must continuously check at the inspection time, and thus cannot perform other tasks in parallel, and thus, the urine test rod is a factor that lowers work efficiency.

In recent years, test rods have been used not only for urine tests but also for saliva, blood tests, alcohol, gasoline and the like, but the above-described problems occur in the same way.

Therefore, a method for solving the problem of the test rod according to the prior art is urgently required.

The present invention is to solve the above-mentioned problems of the prior art, one side of the present invention is the flow portion and time scale is arranged on the test sheet, the test time from the moving distance of the urine flows into the flow portion at the same time as the test starts To provide a test strip that can measure the.

In addition, another aspect of the present invention is that the interval of the time division is arranged non-linearly, or the width of the flow portion is formed to become narrow gradually, to offset the time error that occurs when the moving speed of the test liquid moving along the flow portion is slowed down. To provide a test strip.

Test strip according to an embodiment of the present invention is formed in a plate shape having a predetermined length, one end of the test sheet is immersed in the test liquid; A reagent pad disposed on one surface of the test sheet and discolored in response to the test liquid; A flow part disposed on the test sheet along a length direction of the test sheet and moving the test liquid absorbed to one end in the other end direction when the test sheet is immersed; And a time scale unit displaying an inspection time corresponding to the moving distance of the test liquid moving along the flow unit.

On the other hand, the test strip according to another embodiment of the present invention is formed in a plate shape having a predetermined length, one end of the test sheet immersed in the test liquid; A reagent pad disposed on one surface of the test sheet and discolored in response to the test liquid; It is formed in the shape of a hollow tube in which capillary force is generated, and is disposed on the test sheet along the longitudinal direction of the test sheet, and moves the test liquid absorbed in one end when the test sheet is immersed in the other end direction. Flow section; And a time scale unit displaying an inspection time corresponding to the moving distance of the test liquid moving along the flow unit.

On the other hand, the test strip according to another embodiment of the present invention is formed in a plate shape having a predetermined length, one end of the test sheet immersed in the test liquid; A reagent pad disposed on one surface of the test sheet and discolored in response to the test liquid; A flow portion that penetrates the inside of the inspection sheet along the longitudinal direction of the inspection sheet and moves the test liquid absorbed in one end when the inspection sheet is immersed in another direction by capillary force; And a time scale unit displaying an inspection time corresponding to the moving distance of the test liquid moving along the flow unit.

In addition, in the test strip according to the embodiment of the present invention, the flow portion is formed of a porous material, a rectangular plate shape.

Further, in the test strip according to the embodiment of the present invention, the flow portion is paper.

In addition, in the test strip according to an embodiment of the present invention, a hydrophobic material, the coating layer covering the exposed one surface of the flow portion; further includes.

In addition, in the test strip according to the embodiment of the present invention, the test liquid is urine, saliva, blood, drinking water, alcohol, or gasoline.

In addition, in the test strip according to an embodiment of the present invention, the reagent pads are changed into different colors according to the components of the test liquid or the test time, and colorimetrically arranged with a plurality of display colors indicating colors of the reagent pads. Table; It further includes.

Further, in the test strip according to the embodiment of the present invention, the time interval of the time division portion becomes narrower gradually toward the other end of the flow portion.

In addition, in the test strip according to the embodiment of the present invention, the width of the gas flow portion becomes narrower toward the other end.

In addition, the test strip according to an embodiment of the present invention, is connected to one end of the flow portion, the reservoir containing the test liquid when the test sheet is immersed in the test liquid; further includes a.

Further, in the test strip according to the embodiment of the present invention, one end of the flow portion and the reagent pad are disposed on the same parallel line parallel to one end of the test sheet.

In addition, in the test strip according to an embodiment of the present invention, the flow portion is formed entirely or a predetermined portion transparent to confirm the movement of the test liquid from the outside.

In addition, in the test strip according to an embodiment of the present invention, the absorber disposed inside the flow portion, formed of a porous material; further includes.

In addition, in the test strip according to the embodiment of the present invention, one end of the absorbent material is exposed to the outside.

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

Prior to this, the terms or words used in this specification and claims are not to be interpreted in a conventional and dictionary sense, and the inventors may appropriately define the concept of terms in order to best describe their own invention. It should be interpreted as meaning and concept corresponding to the technical idea of the present invention based on the principle that the present invention.

According to the present invention, since the flow portion and the time scale are arranged on the inspection sheet, the moving distance of the test liquid flowing into the flow portion at the same time as the start of the inspection is converted into time through the time scale, without using a separate timer. As a result, the inspection time can be easily confirmed.

In addition, according to the present invention, the interval of the time scale is arranged non-linearly, or the width of the flow portion is formed to become narrow gradually, by offsetting the time error due to the moving speed that changes as the inspection time elapses, thereby accurately measuring the inspection time There is an advantage that can improve the accuracy of the inspection.

1 is a perspective view of a test strip according to a first embodiment of the present invention.
2A-2B are enlarged views of circle A shown in FIG. 1.
3 is a perspective view of a test strip according to a second embodiment of the present invention.
4 is a perspective view of a test strip according to a third embodiment of the present invention.
5 is a perspective view of a test strip according to a fourth embodiment of the present invention.

The objects, specific advantages and novel features of the present invention will become more apparent from the following detailed description and the preferred embodiments associated with the accompanying drawings. In the present specification, in adding reference numerals to the components of each drawing, it should be noted that the same components as possible, even if displayed on different drawings have the same number as possible. In addition, terms such as “first” and “second” are used to distinguish one component from another component, and the component is not limited by the terms. In the following description, detailed descriptions of related well-known techniques that may unnecessarily obscure the subject matter of the present invention will be omitted.

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

1 is a perspective view of a test strip according to a first embodiment of the invention, and FIGS. 2A-2B are enlarged views of circle A shown in FIG. 1.

As shown in Figure 1, the test strip according to the first embodiment of the present invention is formed in a plate shape having a predetermined length, the test sheet 10, one end 11 is immersed in the test liquid 1, The test pad 10 is disposed on one surface of the test sheet 10 and is disposed on the test sheet 10 along the length direction of the reagent pad 20 and the test sheet 10 which are discolored in response to the test liquid 1, and the test sheet 10. When the liquid 10 is immersed, the flow of the test liquid 1 absorbed in one end corresponds to the moving part 30 moving in the other end direction, and the moving distance of the test liquid 1 moving along the flow part 30. It includes a time scale 40 for displaying the inspection time.

The test strip according to the present embodiment is a test rod for analyzing the components of the test liquid 1, and includes a test sheet 10, a reagent pad 20, a flow part 30, and a time scale part 40. .

In the process of diagnosing the patient, a urine test, a saliva test, and a blood test are performed to determine the name of the disease and to examine the symptoms. Urine is a waste product after filtering blood from the kidney and contains various metabolites. Thus, urine tests can easily obtain information about abnormalities of the urinary tract system as well as systemic endocrine / metabolic diseases. Saliva tests can measure a variety of hormones, especially for diagnosis of adrenal fatigue. Blood test is a test that occupies most of the clinical test, it is possible to determine the blood cell count and normal physiological function. In order to carry out this test method simply and non-invasively, the test strip according to this embodiment was devised. That is, the test strip according to the present embodiment is used to read urine, saliva, or blood into the test solution 1, and analyze the components thereof to read out the target disease. At this time, the component analysis of the test liquid (1) is based on the color change of the reagent pad 20, so long as the component of the test liquid (1) has a property of discoloring through a chemical reaction with the reagent pad 20, Various types of test liquids 1 can also be determined. Therefore, the test solution 1 is not necessarily limited to urine, saliva, or blood, and may include any substance that is discolored by reacting with the reagent pad 20, such as drinking water, alcohol, or gasoline. have.

Here, the test sheet 10 is formed in a plate shape having a predetermined length as a support. In order to test the test liquid (1), one end 11 of the test sheet 10 is immersed in the test liquid (1) contained in a container, etc. At this time, one end 11 of the test sheet 10 is the test liquid ( It is not necessary to maintain the state immersed in 1), and once the test liquid 1 is on the end 11, the test sheet 10 is placed on a table or a test table, and the color change of the reagent pad 20 is carried out. You may observe.

The reagent pad 20 is a reaction part discolored by the test liquid 1 and is disposed on one surface of the test sheet 10 serving as a support. Here, the reagent pad 20 may be disposed at a predetermined position on the test sheet 10 to be immersed together when one end of the test sheet 10 is immersed in the test liquid 1. However, since the test liquid 1 absorbed at one end of the test sheet 10 may move along the test sheet 10, the test liquid 10 is not necessarily disposed to be immersed together with the test sheet 10. In this case, the test liquid 1 may move along the tissue of the material due to the material property of the test sheet 10 or may move through a hollow channel penetrated from one end of the test sheet 10 to the reagent pad 20. (Not shown).

The reagent pad 20 contains a chemical component and changes its color when it reacts with a specific component of the test liquid 1. For example, when the test solution (1) is urine, the metabolite contained in the urine of a patient with a particular disease is different from the normal person in its concentration or type, so that the reagent pad (20) responding to the urine of the patient ) Shows a different color from the reagent pad 20 in response to the urine of normal persons. Therefore, the component of the test solution 1 may be determined or the target disease may be determined through the color change of the reagent pad 20. At this time, in determining the color of the reagent pad 20, the inspection time required for the determination must be observed. This is because the inspection time can range from several seconds to several minutes depending on the type of test liquid 1 and the inspection purpose. For example, in the case of urinalysis, the target disease is determined based on the color determined within 60 to 120 seconds. That is, the color of the reagent pad 20 depends on the type of test liquid 1 and the test time. Therefore, in order to make an accurate inspection, it is strictly required to observe the inspection time, the test strip according to the present embodiment can measure the inspection time without a separate timer through the flow unit 30 and the time scale 40. .

The flow part 30 is a channel through which the test liquid 1 flows. Here, the flow part 30 is arrange | positioned along the longitudinal direction of the test | inspection sheet 10 on the test | inspection sheet 10 so that the test liquid 1 may flow in to one end, and may move to the other end direction. At this time, the test liquid 1 is moved by capillary force generated in the flow part 30. Specifically, the flow part 30 may be formed in a rectangular plate shape having a predetermined width and length as a porous material. In this case, since a paper may be used as a representative porous material, the paper may be cut in a rectangle to form a flow part 30. Since the paper is composed of cellulose fibrin, the test liquid 1 is transported by generating capillary force through numerous pores without a separate device. However, the porous material is not necessarily limited to the species, and as long as the liquid can permeate along the inside thereof by capillary force, such as fabric, cotton, fiber, membrane, etc., the flow part 30 ) May also be formed of various materials without necessarily being formed of paper. The test liquid 1 moving along the flow part 30 moves at a predetermined speed, and the test time can be measured by arranging the time scale part 40 to fit the moving distance.

Here, the time scale part 40 includes the time scale 41 which displays the time converted from the moving distance of the test liquid 1. Since the test liquid 1 moves a predetermined distance for a predetermined time at a predetermined moving speed in the flow part 30, if the time scale 41 is displayed according to the moving distance, the moving distance of the test liquid 1 In response, the travel time can be checked immediately. At this time, the test liquid 1 flows into one end of the flow part 30, and since the test starts from that time, when the end is set as the reference point of time, the time grasped from the time scale 41 becomes the test time. .

In view of this fact, one end of the flow section 30 and the reagent pad 20 may be arranged in parallel with each other so that the test time is measured simultaneously with the reaction of the reagent pad 20. That is, one end of the flow section 30 and the reagent pad 20 are disposed on the same parallel line l parallel to the one end 11 of the test sheet 10, so that the test liquid 1 simultaneously holds the reagent pad 20. ) And the one end of the flow portion 30, the time scale 40 is to measure the reaction time of the reagent pad (20). However, as described above, the test liquid 1 may be absorbed into the reagent pad 20 through the tissue or the hollow channel of the test sheet 10, or another configuration may be added. The reagent pads 20 do not have to be arranged side by side.

On the other hand, the time scale 41 may be displayed on one surface of the inspection sheet 10 or the outer surface of the flow portion 30, wherein the interval of the time scale 41 is linear or depending on the shape of the flow portion 30 , Or may be disposed non-linearly. This will be described in detail below.

Depending on the type of the test liquid 1, the speed of the test liquid 1 moving along the flow part 30 may be variable. That is, while there is a test liquid 1 moving at almost the same speed from one end to the other end of the flow part 30 during the inspection time, the test liquid 1 whose speed drops significantly away from the end of the flow part 30. have. In the case of the speed-variable test liquid (1), the moving distance is greatly changed according to the same time interval, so that the time error through the time scale 41 is excessive, it should be compensated for this. As the compensation method, the test strip according to the present embodiment non-linearly indicated the interval of the time scale 41, or adjusted the width of the flow section 30, each case will be described in detail.

As shown in FIG. 2A, the intervals of the time divisions 41a, 41b, and 41c of the time division unit 40 may be gradually narrowed toward the other end of the flow unit 30. When the width w of the flow part 30 is constant, the moving distance of the speed-variable test liquid 1 moving for the same time becomes shorter toward the other end of the flow part 30. Therefore, the space L ₂ between two time scales 41b and 41c close to the other end of the flow part 30 is the distance between two time scales 41a and 41b close to one end of the flow part 30. The time scales 41a, 41b, and 41c are arranged to be relatively shorter than (L ₁ ) to compensate for the time error according to the variable speed. Alternatively, the time error may be offset while maintaining the time intervals 41a, 41b, 41c at equal intervals, which will be described below.

As shown in FIG. 2B, the width w of the flow part 30 is formed to become narrower toward the other end, thereby offsetting the time error. The wider portion w of the flow portion 30 has a larger cross-sectional area than the narrow portion, so that the area of the pores through which the test liquid 1 passes is also wider. At this time, since the moving speed of the test liquid 1 is faster in a portion having a relatively small pore area, that is, a narrow width w, the width w of the flow part 30 in the other end becomes narrower, The test liquid 1 moves at a constant speed. Thus, since the test liquid 1 moves at a constant speed, the interval L ₂ between two time scales 41b and 41c close to the other end of the flow part 30 and two times close to one end of the flow part 30. Even if the interval L ₁ between the graduations 41a and 41b is the same, accurate time measurement becomes possible.

As a result, according to the test strip according to the present embodiment, the flow part 30 and the time scale 41 are disposed on the test sheet 10, so that the test liquid flowing into the flow part 30 at the same time as the start of the test is moved. By converting the moving distance of (1) into time through the time scale 41, there is an effect that can easily check the inspection time with the naked eye without the need to use a separate timer. In addition, the interval of the time scale 41 is arranged non-linearly, or the width of the flow section 30 is formed to become narrow gradually, to compensate for the time error due to the moving speed that changes as the inspection time passes, so that the inspection time accurately This has the advantage of improving the accuracy of the test by measuring.

3 is a perspective view of a test strip according to a second embodiment of the present invention.

As shown in FIG. 3, the test strip according to the second embodiment of the present invention may further include a coating layer 50. The coating layer 50 is a thin film layer made of a hydrophobic material and covers one surface of the flow part 30. Here, one surface of the flow part 30 means the other side of the surface in contact with the test sheet 10, that is, the surface exposed to the outside. Hydrophobic material is coated or printed on one surface of the flow part 30 made of a porous material such as paper to form a coating layer 50, thereby controlling the permeability of the flow part 30, thereby controlling the flow of the test liquid 1. Can be controlled. In addition, although the test liquid 1 should be introduced from one end of the flow part 30, the coating layer 50 may unintentionally bury the test liquid 1 in the center of the flow part 30 due to a mistake of the user, or the like. Foreign matter affecting the inspection is prevented from contacting the flow part (30). Here, the hydrophobic material may be, for example, wax or polymer series, so that the coating layer 50 may be formed by printing the wax by wax printing or by casting and drying the polymer ink. Here, the polymer may be, for example, polystyrene, but is not necessarily limited thereto. In addition, the hydrophobic material is not necessarily limited to wax or polymer series, and may include various materials as long as they have hydrophobicity such as SU-8 or alkenyl ketene dimer.

In addition, the test strip according to the present embodiment may further include a colorimetric table 60. Here, the color table 60 is a table in which various display colors 61a and 61b of the reagent pad 20 reacted with the test liquid 1 are arranged. At this time, since the display colors 61a and 61b constituting the colorimetric table 60 are predetermined colors depending on the disease or the component of the test solution 1, the color of the reagent pad 20 is contrasted with the colorimetric table 60. The disease and the test liquid (1) component can be immediately determined. Here, the display colors 61a and 61b are disposed to be adjacent to each other along the edge of the reagent pad 20, and the reagent pad 20 and the colorimetric table 60 are paired in a one-to-one relationship with each other, and thus, at least one. It may be arranged above. When arranged in plural pairs, various diseases or components of the test liquid 1 can be determined by one test, so that the test time can be shortened and the test efficiency can be improved.

In addition, the test strip according to the present embodiment may further include a reservoir 70. Here, the reservoir 70 temporarily receives the test liquid 1 when the test sheet 10 is immersed in the test liquid 1. Specifically, the reservoir 70 may be formed in various forms and materials, such as a container, or a pad form capable of absorbing the test liquid 1 as a porous material as long as the test liquid 1 may be stored. Since the reservoir 70 is connected to one end of the flow part 30, the test liquid 1 temporarily accommodated in the reservoir 70 is absorbed through one end of the flow part 30.

In the above-described embodiment, the flow part 30 is formed of a porous material, but may be formed in a hollow tube shape, which will be described below.

4 is a perspective view of a test strip according to a third embodiment of the present invention, and FIG. 5 is a perspective view of a test strip according to a fourth embodiment of the present invention.

As shown in Figure 4, the test strip according to the third embodiment of the present invention is formed in a plate shape having a predetermined length, one end of the test sheet 10, the test sheet ( 10 is disposed on one surface of the reagent pad 20, which is discolored in response to the test liquid 1, and is formed in a hollow tube shape in which capillary forces are generated, and along the longitudinal direction of the test sheet 10, the test sheet ( 10 is disposed on 10, the test liquid (1) to move the test liquid (1) absorbed in one end when the test sheet 10 is immersed in the other end direction, and the test liquid moving along the flow unit (30a) And a time scale unit 40 for displaying the inspection time corresponding to the moving distance of (1).

As shown in Figure 5, the test strip according to the fourth embodiment of the present invention is formed in a plate shape having a predetermined length, one end of the test sheet 10, the test sheet ( The test pad 10 is disposed on one surface of the test sheet 10 and penetrates through the inside of the test sheet 10 along the length direction of the reagent pad 20 and the test sheet 10 which are discolored in response to the test liquid 1. ) When the test liquid 1 absorbed in one end is moved to the other end direction by the capillary force, and the moving distance of the test liquid 1 moving along the flow part 30b. And a time scale 40 for displaying the corresponding inspection time.

The test strip according to the third to fourth embodiments of the present invention includes a test sheet 10, a reagent pad 20, flow parts 30a and 30b, and a time scale part 40. Except for 30b), it is the same as the test strip (see FIG. 1) according to the first embodiment described above. Therefore, overlapping portions will be omitted or simply described, and the differences will be described.

The flow portion 30a of the test strip according to the third embodiment of the present invention is formed in a hollow tube shape in which capillary force is generated, and is disposed on the test sheet 10. On the other hand, the flow portion 30b of the test strip according to the fourth embodiment penetrates into a hollow tube shape in which capillary force is generated, and is formed in the test sheet 10.

In the test strips according to the third and fourth embodiments, the test liquid 1 is transported by capillary force, and may further include an absorbent 80 to control the moving speed of the test liquid 1. have. Here, the absorbent material 80 is a porous material disposed inside the flow parts 30a and 30b and may be, for example, paper, fabric, cotton, or fiber. However, the material is not limited thereto. At this time, one end of the absorber 80 may be exposed to the outside. In this case, even if one end of the flow section (30a, 30b) is not in direct contact with the test liquid (1), such as being immersed in the test liquid (1), if one end of the absorber 80 is in contact with the test liquid (1) inspection time Measurement is possible.

In addition, the test strips according to the third and fourth embodiments may be formed in whole or in part so that the test liquid 1 moving in the flow parts 30a and 30b can be visually checked from the outside.

In addition, the test strips according to the third and fourth embodiments may include all of the features of the above-described first and second embodiments (see FIGS. 1 and 2). Therefore, in the test strip according to the present embodiment, one end of the flow portion (30a, 320b) and the reagent pad 20 can be arranged side by side, the interval between the time division 41 of the time division portion 40 It may be formed to become narrower toward the other end of the eastern portion (30a, 30b), or the inner diameter of the flow portion (30a, 30b) becomes smaller toward the other end to offset the time error. In addition, the colorimetric table 60 and / or reservoir 70 may be disposed on the test sheet 10. Specific details have been described in the first and second embodiments, and detailed descriptions thereof will be omitted.

Although the present invention has been described in detail through specific examples, it is intended to describe the present invention in detail, and the present invention is not limited thereto, and should be understood by those skilled in the art within the technical spirit of the present invention. It is obvious that modifications and improvements are possible.

All modifications and variations of the present invention fall within the scope of the present invention, and the specific scope of protection of the present invention will be apparent from the appended claims.

1: Test liquid 10: Inspection sheet
20: reagent pads 30, 30a, 30b: flow section
40: time scale 41: time scale
50: coating layer 60: colorimetric table
61: display color 70: reservoir
80: absorbent material

Claims (3)

An inspection sheet formed in a plate shape having a predetermined length and having one end immersed in the test liquid;
The test liquid is formed in the shape of a hollow tube in which capillary force is generated, and is disposed on the test sheet along a length direction of the test sheet, and the test liquid absorbed to one end when the test sheet is immersed through the inside of the hollow tube. Moving in the direction, the flow portion having a constant width in the longitudinal direction;
When the test sheet is immersed, the absorbed test liquid comes into contact with the absorbed test liquid, so that the test liquid is absorbed only by the exposed end, and is disposed inside the hollow tube of the flow part. Absorbing material absorbs the test liquid, and control the moving speed, the width is narrowed toward the other end has the other end spaced apart without contacting the inner surface of the flow portion, the remaining portion except the exposed one is located in the flow portion;
A time scale unit which displays an inspection time corresponding to a moving distance of the test liquid moving along the flow unit; And
A plurality of reagent pads disposed on one surface of the test sheet and discolored in response to the test liquid and arranged spaced apart along the flow portion;
Include a plurality of color palettes surrounding each of the plurality of reagent pads,
The plurality of reagent pads include a color change by reacting with different components,
And the absorbent material comprises a first portion in contact with the inner surface of the flow portion and adjacent to the exposed one end, and a second portion spaced apart without contacting the inner surface of the flow portion.
According to claim 1,
The test liquid is urine, saliva, blood, drinking water, liquor, or gasoline.
According to claim 1,
And the flow portion is a test strip in which a whole or a predetermined portion is formed to be transparent so as to confirm the movement of the test liquid from the outside.

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