KR20170028542A - ESR analysis system using infrared rays - Google Patents

Abstract

The present invention relates to an erythrocyte sedimentation rate (ESR) analysis system using infrared rays, capable of correctly and automatically performing a test while preventing occurrence of measurement deviation according to a tester in advance, so as to remarkably reduce test expenses and time. According to the present invention, the ESR analysis system comprises: an infrared rays generation unit emitting infrared rays; a first polarization unit installed on a rear side of the infrared rays generation unit to pass only a vertically polarized wave among the infrared rays emitted from the infrared rays generation unit; a sample storage unit installed on a rear side of the first polarization unit, receiving the vertically polarized wave and containing erythrocyte, i.e. the sample; a second polarization unit installed on a rear side of the sample storage unit to pass only the horizontally polarized wave among refracted infrared rays passing through the sample storage unit; a light reception unit installed on a rear side of the second polarization unit and making the infrared rays passing through the second polarization unit converged thereto; and an analysis unit analyzing a wavelength of the infrared rays converged to the light reception unit.

Description

[0001] ESR analysis system using infrared rays [

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an infrared erythrocyte sedimentation rate analysis system, and more particularly, to an infrared erythrocyte sedimentation rate analysis system capable of automatically and accurately performing ESR analysis.

The Erythrocyte sedimentation rate test is a method in which the blood is placed in a test tube and the erythrocytes are separated from the plasma when they are placed vertically for a certain period of time. Thus, by measuring the distance to the sedimentation line of red blood cells This test is used to help diagnose the disease.

However, most of these ESR tests are performed manually by hospitals or by automated equipment.

Therefore, there is a problem that the accuracy and consistency of the test results are deteriorated due to an error in the result according to the skill or the condition of the worker performing the test, and a lot of time and cost are required for the measurement and analysis.

As a method for solving this problem, there has been developed and introduced an erythrocyte sedimentation velocity measuring device as shown in Korean Registered Patent Publication No. 110-0844532 (Bulletin of 12008.7.8), but the test is mainly performed by hand It is difficult to use it in the actual field because it has the problem that occurred before, such as the skill is required for the equipment.

Korean Registered Patent Publication No. 110-0844532 (Announcement No. 12008.7.8)

It is an object of the present invention to precisely inspect and to prevent the occurrence of a measurement error according to an inspector, and to automatically perform inspection, And to provide an infrared erythrocyte sedimentation rate analysis system that can be easily tracked and can significantly reduce inspection cost and time.

It is another object of the present invention to provide a system for analyzing erythrocyte sedimentation rate using infrared rays, which is simple and easy to maintain, and has a small number of failures.

According to an embodiment of the present invention, there is provided a system for analyzing erythrocyte sedimentation rate using infrared rays,

An infrared ray generator for emitting infrared rays,

A first polarizer provided at a rear side of the infrared ray generator and passing only vertical polarized waves of infrared rays emitted from the infrared ray generator,

A sample storage unit provided at the rear side of the first polarizing unit and containing the red blood cells,

A second polarizer provided behind the sample storage unit and passing only the horizontal polarized wave out of the refracted infrared rays transmitted from the sample storage unit,

A light receiving portion provided on the rear side of the second polarizing portion and converging infrared rays that have passed through the second polarizing portion,

And an analyzer for analyzing the wavelength of the infrared light converged in the light receiving unit

Red blood cell sedimentation rate analysis system using infrared

Wherein the infrared ray generator, the first polarizer, the second polarizer, and the light receiver are positioned on a straight line,

And a driving unit for vertically moving the infrared ray generator, the first polarizing unit, the second polarizing unit, and the light receiving unit vertically.

In addition,

A timer, and a storage unit,

Receiving a wavelength value of infrared rays converging to the light receiving unit at regular time intervals,

Storing a variation point of an input infrared wavelength value in the storage unit,

The stored mutation points are connected by time zone to form a curve,

And comparing the formed curve with a reference curve stored in the storage unit.

In addition, the sample storage section

A tube body made of a transparent material and having a tubular shape having a hollow circular cross section,

A holding portion provided at a lower portion of the upper end portion of the tubular body to be inserted in an interference fit state and a hollow pressurizing deformation portion having a larger cross-

An inner ball which is installed inside the tubular body and has an outer diameter smaller than an inner diameter of the tubular body so as to be movable in the tubular body and is made of a material having a specific gravity smaller than blood,

And a ring-shaped ball blocking ring which is engaged with the upper end of the tube and whose inner diameter is smaller than the outer diameter of the inner ball.

In addition, the upper end portion of the tubular body is provided with a shaft-diameter portion having a relatively small outer diameter of the outer circumferential surface, and the entire diameter-reduced portion is located inside the receiving portion of the grip portion when the tubular body and the grip portion are engaged,

And the protruding portion is formed on the inner circumferential surface of the receiving portion of the grip portion so as to correspond to the reduced diameter portion and engage with the reduced diameter portion.

The inner peripheral surface of the reduced diameter portion of the tubular body is provided with an enlarged diameter portion having a relatively large inner diameter,

The ball blocking ring is partially inserted into the enlarged diameter portion, and a protrusion is formed on the lower side, and the protrusion is inserted into the lower side tube of the enlarged diameter portion.

In addition, the ball blocking ring is partially inserted into the upper end portion of the tube by interference fit

And an outer diameter of a portion of the ball blocking ring that is not inserted into the enlarged diameter portion is the same as the outer diameter of the tubular body and is located in the receiving portion.

In addition, a ball blocking bar formed to cross the inner circumferential surface is provided in the lower end of the tubular body to prevent the inner ball from coming off.

Through the above-described problems, the infrared erythrocyte sedimentation rate analyzing system of the present invention can accurately inspect and prevent the measurement deviation from occurring according to the inspector, and the inspection is automatically performed. Thus, It is easy to track, and the inspection cost and time can be remarkably reduced. Moreover, there is an advantage such that the apparatus is simple, the occurrence of trouble is less, and maintenance is easy.

1 is a conceptual view briefly showing a main part of an erythrocyte sedimentation rate analysis system using infrared rays according to the present invention.
2 is a perspective view showing a sample storage unit according to the present invention.
3 is an exploded perspective view showing a sample storage unit according to the present invention.
4 is a cross-sectional view illustrating a sample storage unit according to the present invention.
FIG. 5 is a conceptual diagram showing an operation process of an erythrocyte sedimentation rate analysis system using infrared rays according to the present invention.
6 is a diagram briefly showing an analysis method of an erythrocyte sedimentation rate analysis system using infrared rays according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of an infrared erythrocyte sedimentation rate analyzing system of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 is a perspective view illustrating a sample storage unit according to the present invention. FIG. 3 is a cross-sectional view illustrating a sample storage unit according to an embodiment of the present invention. FIG. 5 is a conceptual diagram showing an operation process of an erythrocyte sedimentation rate analyzing system using infrared rays according to the present invention. FIG. 6 is a graph showing an erythrocyte sedimentation rate FIG. 1 is a diagram schematically showing an analysis method of an analysis system. FIG.

1, the system for analyzing erythrocyte sedimentation velocity using infrared rays includes an infrared ray generator 10, a first polarizer 20, a sample storage 100, a second polarizer 40, An analyzing unit 50, an analyzing unit 60, and a driving unit.

First, the infrared ray generator 10 uses an infrared ray having a wavelength of 900 nm in the measurement of the erythrocyte sedimentation velocity, and an infrared lamp or the like is used as a part for generating the infrared ray.

The first polarizing section 20 is disposed behind the infrared ray generating section 10 and blocks the horizontal polarized wave from the infrared ray emitted from the infrared ray generator 10 and passes only the vertical polarized wave. Lens or the like is used.

The sample storage unit 100 is provided on the rear side of the first polarizing unit 20 and includes the red blood cells as the sample to which the vertical polarized wave is inputted.

2 to 4, the sample storage unit 100 includes a tubular body 110, a grip 120, an inner ball 130, a ball blocking ring 140, and the like.

Here, the tube 110 is a portion in which liquid is sucked in, and is made of a transparent synthetic resin, glass, or the like, and has a tube shape having a hollow circular cross section.

A scale may be formed along the longitudinal direction of the tube 110.

The grip portion 120 is provided at an upper portion of the tube 110 to form a negative pressure to allow liquid to flow into the tube 110. The grip portion 120 includes a receiving portion 121 at a lower portion thereof, (122).

The accommodating portion 121 is a tube-shaped portion into which the upper end of the tube 110 is inserted in an interference fit, and the pressurizing deformation portion 122 has a larger cross-sectional area than the accommodating portion 121, And the receiving portion 121 and the press deforming portion 122 are integrally made of synthetic resin or rubber having elasticity.

The inner volume of the pressure-deforming portion 122 is preferably larger than the inner volume of the tube 110.

The inner ball 130 is a sphere-shaped component provided inside the tube 110. The inner ball 130 has a smaller outer diameter than the inner diameter of the tube 110, And is made of a material having a smaller specific gravity than blood, so that it is preferable to float when liquid such as blood flows.

The ball blocking ring 140 is inserted into an upper end portion of the tube 110 in an interference fit with the inner circumference of the ball blocking ring 140. The inner diameter of the ball blocking ring 140 is smaller than the outer diameter of the inner ball 130, Shape.

The ball blocking ring 140 is made of elastic synthetic resin, silicone rubber, or the like.

The ball blocking ring 140 may be formed simply as a ring without the insertion portion.

In addition, the upper end of the tubular body 110 is provided with a reduced-diameter portion 111 having a relatively small outer diameter of the outer circumferential surface, and the entirety of the reduced- And is located inside the receiving portion 121 of the grip portion 120. [ As a result, when the tubular body 110 is inserted into the receptacle 121, the contact area is reduced to facilitate insertion, and the shrinkage of the grip 120 due to the shrinkage of the grip 120, Thereby preventing the tubular body 110 from separating from the gripper 120.

The grip portion 120 may further include a protrusion 123 formed on the inner circumferential surface of the receiving portion 121 and corresponding to the reduced diameter portion 111 to engage with the reduced diameter portion 111. The tubular body 110 and the receiving portion 121 can be firmly coupled with each other.

A diameter enlarged portion 112 having a relatively large inner diameter is provided on the inner peripheral surface of the reduced diameter portion 111 of the tubular body 110. The ball blocking ring 140 is partially inserted into the enlarged diameter portion 112, A protrusion 141 having a smaller outer diameter is formed on the lower side and the protrusion 141 is configured to be inserted into the lower side tube 110 of the enlarged diameter portion 112. As a result, the contact surface between the ball blocking ring 140 and the inside of the tube 110 is widened to prevent leakage of the fluid to the outside of the ball blocking ring 140, and a semi-spherical protrusion 141 The leakage of the fluid between the inner ball 130 and the ball blocking ring 140 can be prevented.

The outer diameter of the portion of the ball blocking ring 140 that is not inserted into the enlarged diameter portion 112 is the same as the outer diameter of the tube 110 and is located inside the accommodating portion 121.

In addition, a ball blocking bar 113 is formed in the lower end of the tube 110 to prevent the inner ball 130 from being separated from the inner circumferential surface. Accordingly, the ball located inside the tubular body 110 is prevented from being released to the outside.

A method of using and operating the sample storage unit 100 will be described. First, the pressurizing and deforming unit 122 of the grip unit 120 is pressed and deformed while holding the grip unit 120.

Then, the lower part of the tube 110 is introduced into a liquid such as blood to be sucked.

When the pressurization of the pressure-deforming portion 122 is stopped, liquid such as blood flows into the tubular body 110.

At this time, due to the introduced liquid, the inner ball 130 rises to come in contact with the ball blocking ring 140, and the inner ball 130 blocks the hole of the ball blocking ring 140, The inner ball 130 is restricted from being separated from the ball blocking ring 140 due to the negative pressure formed due to the deformation of the press deforming portion 122.

Through this process, the sample storage unit 100 can not only flow a fixed amount of liquid but also restrict the discharge after the liquid is introduced.

The second polarizing unit 40 is disposed behind the sample storage unit 100 and blocks vertically polarized waves of the refracted infrared rays passing through the sample storage unit 100 and passes only horizontal polarized waves. A used polarizing lens or the like is used.

The light receiving portion 50 is a portion provided on the rear side of the second polarizing portion 40 and converging on the infrared rays that have passed through the second polarizing portion 40.

Here, the infrared ray generator 10, the first polarizer 20, the second polarizer 40, and the light receiver 50 are positioned on a straight line parallel to the ground.

The analyzer 60 includes a timer and a storage unit for analyzing the wavelength of the infrared light converged in the light receiver 50. The analyzer 60 includes a light receiving unit 50, the wavelengths of the infrared rays converged at predetermined time intervals are received at predetermined time intervals, and as shown in FIG. 6, the variable points of the input infrared wavelength values are stored in the storage unit, And comparing the thus formed curve with the reference curve stored in the storage unit to compare the time difference to display on a separate display device with a graph or the like, or to perform a matching diagnosis on a singularity to display the symptom.

The driving means is means for repeating the vertical rising and falling of the infrared ray generating unit 10, the first polarizing unit 20, the second polarizing unit 40 and the light receiving unit 50 at the same speed, A control device is provided so that the operator can adjust the ascending / descending speed. The driving means may be a mechanical element that enables a linear motion of a driving motor, a belt, and an LM guide.

Through the above-described configuration, the ESR analysis system using infrared rays of the present invention can accurately inspect, prevent measurement errors from occurring according to the inspector, and automatically perform the inspection, thereby diagnosing and tracking diseases And it is possible to remarkably reduce the inspection cost and time, and it is also advantageous in that the apparatus is simple, the occurrence of trouble is less, and maintenance is easy.

10: Infrared ray generator
20: first polarizing portion
40: second polarizing portion
50:
60: Analytical Department
100: Sample storage unit
110: pipe body 111:
112: diameter portion 113: ball blocking bar
120: grip portion 121: accommodating portion
122: pressure-deforming portion 123:
130: Inner ball
140: ball blocking ring 141: protrusion

Claims (2)

An infrared ray generator for emitting infrared rays,
A first polarizer provided at a rear side of the infrared ray generator and passing only vertical polarized waves of infrared rays emitted from the infrared ray generator,
A sample storage unit provided at the rear side of the first polarizing unit and containing the red blood cells,
A second polarizer provided behind the sample storage unit and passing only the horizontal polarized wave out of the refracted infrared rays transmitted from the sample storage unit,
A light receiving portion provided on the rear side of the second polarizing portion and having infrared rays that have passed through the second polarizing portion converge;
And an analyzer for analyzing the wavelength of the infrared light converged in the light receiving unit
Red blood cell sedimentation rate analysis system using infrared
The method according to claim 1,
Wherein the infrared ray generator, the first polarizer, the second polarizer, and the light receiver are positioned on a straight line,
Further comprising driving means for vertically raising and lowering the infrared ray generator, the first polarizer, the second polarizer, and the light receiver.
Red blood cell sedimentation rate analysis system using infrared

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