KR101246408B1 - Atomic absorption analysis - Google Patents

Abstract

PURPOSE: An atomic absorption analyzing device is provided to facilitate to draw a calibration curve having a high directivity as a light transmission distance is adjustable. CONSTITUTION: An atomic absorption analyzing device comprises a burner head(100), a rotary unit(200), a chamber(300), and a position determination unit. The rotary unit is arranged in the lower part of the burner head. The chamber supports the rotary unit. The position determination unit determines a rotating position of the rotary unit. The rotary unit includes a body(210) protruded from the bottom of the burner head. A hanging protrusion(220) is formed in the outer periphery of the body along a circumference direction. Gradations(A) are formed on the exterior surface of the body at a constant distance.

Description

Atomic Absorption Analysis Device {ATOMIC ABSORPTION ANALYSIS}

The present invention relates to an atomic absorption spectrometer, and more particularly, to an atomic absorption spectrometer capable of adjusting the angle of a burner head.

In general, atomic absorption spectrometry is quantified using the Beer-Lambert law, that is, A = a, b, c (A: absorbance, a: molar extinction coefficient, b: radiation length, c: sample concentration). How to do it.

When the analysis is carried out under the same measurement conditions, the value of the molar extinction coefficient (a) and the length of the radiation pass (b) is a constant value, and the amount of absorbed radiation (absorbance) is determined by the concentration of the sample (c). Is directly proportional to

As the concentration of the sample increases, the straightness of the calibration curve decreases.

Therefore, there is a need for the development of a technique to make the calibration curve straight so that quantitative analysis is possible regardless of the increase in the concentration of the sample.

A prior art document related to the present invention is Korean Patent Publication No. 1991-0009527, which discloses a technique for widening the range of analytical concentration of each element.

SUMMARY OF THE INVENTION An object of the present invention is to provide an atomic absorption spectrometer capable of adjusting the angle of a burner head to an arbitrary angle so as to increase the analysis concentration range of each element.

The present invention includes a burner head; A rotating part provided at a lower end of the burner head; A chamber for rotationally supporting the rotating unit; And a positioning unit for determining a rotation position of the rotating unit.

The rotating part has a circular columnar shape and has a body formed to protrude from the bottom of the burner head, the outer periphery of the body is formed with a locking projection protruding along the circumferential direction, the outer surface of the body above the locking projection It is preferable that a regular interval is formed.

It is preferable that the lower end of the rotating part is fitted into a hole formed in the chamber, and the locking projection is applied to an area around the hole.

Preferably, the positioning unit includes a positioning hole penetrating the internal space of the chamber, and a positioning bolt for pressing and supporting a body fitted into the positioning hole and inserted into the hole of the chamber.

The rotating unit may include a first rotating unit provided at a lower end of the burner head, and a second rotating unit rotatably supporting the first rotating unit to rotate 360 degrees and being rotatably supported in the chamber.

The first rotating part includes a first body protruding from the lower end of the burner head, a connecting rod extending from the lower end of the first body, and a rotating tool formed at the lower end of the connecting rod,

The second rotating unit has a second pillar formed in a circular column shape to protrude from the lower end of the burner head, and is provided on the upper end of the second body, and the rotary sphere is inserted into the rotary support for supporting the rotary sphere by 360 degrees. A stage is provided.

The outer periphery of the second body is preferably formed with a locking projection protruding along the circumferential direction, a scale of a predetermined interval is formed on the outer surface of the second body above the locking projection.

It is preferable that the lower end of the second rotating part is fitted into a hole formed in the chamber, and the locking projection is applied to an area around the hole.

Preferably, the positioning unit includes a positioning hole penetrating the internal space of the chamber, and a positioning bolt for pressing and supporting a body fitted into the positioning hole and inserted into the hole of the chamber.

The present invention has the effect of adjusting the angle of the burner head to any angle so as to increase the analysis concentration range of each element.

Moreover, since this invention can adjust the passage distance of light, it has the effect that it is easy to prepare a calibration curve which has high straightness.

In addition, the present invention can easily adjust the fine angle by allowing the rotation angle of the burner head to be adjusted in multiple stages.

1 is a perspective view showing an example of the atomic absorption spectrometer of the present invention.
2 is a cross-sectional view taken along the line II ′ of FIG. 1.
3 is a graph showing the calibration curve before rotation of the burner head according to the present invention.
4 is a graph showing the calibration curve after rotation of the burner head according to the invention.
5 is a perspective view showing another example of the atomic absorption spectrometer of the present invention.

Hereinafter, the atomic absorption spectrometer of the present invention will be described with reference to the accompanying drawings.

1 shows an example of an atomic absorption spectrometer of the present invention. 2 shows a coupling state between the chamber and the rotating part.

Referring to FIG. 1, the atomic absorption spectrometer includes a burner head 100, a rotating part 200, a chamber 300, and a positioning part.

The rotary part 200 is formed at the lower end of the burner head 100.

The rotating part 200 is formed in a circular columnar shape, and protrudes from a lower end of the burner head 100.

The rotating part 200 has a body 210 of a circular columnar shape. The outer periphery of the body 210 is formed with a locking projection 220 along the circumferential direction of the body 210.

On the outer surface of the body 210 which is located on the upper side of the locking projection 220 is formed a graduation (A) of a predetermined interval.

The rotating part 200 is connected to the chamber 300, and the chamber 300 rotates and supports the rotating part 200.

The chamber 300 may be a spray chamber.

A hole 310 is formed at one end of the chamber 300. The lower end of the rotating part 200, that is, the lower end of the body 210 is fitted into the hole 310.

The engaging protrusion 220 formed in the body 210 spans an area around the hole 310 of the chamber 300.

Here, the rotating part 200 can be horizontally rotated in a state of being fitted into the hole 310 of the chamber 300.

The positioning unit includes a positioning hole 320 and a positioning bolt (B).

The positioning hole 320 is formed in the chamber 300 and exposes the hole 310 to the outside.

The positioning bolt B is fitted into the positioning hole 320 to be coupled.

Therefore, as the positioning bolt 320 is tightened, the positioning bolt 320 may press the outer surface of the body 210 inserted into the hole 310.

Accordingly, the rotation position of the rotating part 200 may be fixed by the tightening operation of the positioning bolt (B).

Of course, when the angle of the rotating part 200 is to be changed, in the state in which the positioning bolt B is released, the rotation angle of the rotating part 200 is varied and the positioning bolt B is tightened again.

In addition, the outer surface of the body 210 which is located on the upper side of the locking projection 220 is formed a graduation (A) of a predetermined interval. And, the reference scale (not shown) may be formed on the outer periphery of the top of the chamber (300).

Therefore, the rotation angle may be determined using the scale A and the reference scale rotated when the burner head 200 rotates.

Embodiments in accordance with the present invention allow the burner head to be rotated horizontally at the top of the chamber and fix the rotational position using a positioning unit at any rotated position.

Figure 3 shows an example of the calibration curve before the rotation of the burner head according to the present invention. 4 shows an example of the calibration curve after the burner head is rotated.

As shown in FIG. 3, as the concentration of the sample is increased, precise quantitative analysis is difficult before the burner head 200 is rotated.

Referring to FIG. 4, when the burner head 200 is rotated at an angle, the light passing distance can be shortened, and thus a black curve having improved straightness can be obtained.

Accordingly, it is possible to accurately analyze the proportional relationship between absorbance and sample concentration, thereby enabling quantitative analysis even if the sample concentration increases.

5 shows another example of the atomic absorption spectrometer of the present invention.

Referring to FIG. 5, the atomic absorption spectrometer includes a burner head 100, a rotation unit 400, a chamber 300, and a positioning unit.

The configuration of the burner head 100 and the positioning unit is substantially the same as the configuration described above.

The rotary part 400 is formed at the lower end of the burner head 100.

The rotating unit 400 provides a function of rotating the burner head 100 in multiple stages on the chamber 300.

The rotating part 400 includes a first rotating part 410 and a second rotating part 420.

The first rotating part 410 is composed of a first body 411, the connecting table 413, and the rotary sphere 412.

The first body 411 is provided at the lower end of the burner head 100. The first body 411 may be formed in a circular columnar shape.

The connecting table 413 is formed to extend a predetermined length from the lower end of the first body 411.

The rotary sphere 412 is provided at the lower end of the connecting table 413.

The connecting table 413 and the rotating hole 412 may be formed integrally with each other.

The connecting table 413 may be detachable from the first body 411. The detachable manner may be achieved by screwing an upper end of the connecting table 413 to a fastening hole (not shown) formed at the lower end of the first body 411.

The second rotating part 420 is composed of a second body 421, a rotation support end 422, and a locking protrusion 424.

The second body 421 is formed in a circular columnar shape.

The rotary support end 422 is formed to protrude on the upper end of the second body 421. The upper end of the rotary support end 422 is formed with a rotary hole 423 to which the rotary support 412 is rotatably supported.

The locking protrusion 424 protrudes along the circumferential direction from the outer circumference of the second body 421.

The second rotating unit 400 configured as described above is rotatably supported by the chamber 300 to enable horizontal rotation.

The outer circumference of the upper second body 421 of the locking projection 424 is formed with a predetermined interval (A). A reference scale (not shown) may be formed on an outer circumference of the upper end of the chamber 300.

The manner of fixing the rotational position of the burner head 100 by using the positioning unit is the same as described above.

Referring to the above configuration, the rotation angle of the burner head 100 may be used in combination with the horizontal rotation and 360 degree rotation.

First, the second rotation part 400 is horizontally rotated at the upper end of the chamber 300 to rotate the burner head 100 at a predetermined angle.

Then, the second rotating unit 400 is fixed at the rotated position by using the positioning unit.

Subsequently, the burner head 100 may be additionally finely adjusted by using the first rotation part 410 rotated 360 degrees to the rotation support end 422 of the second rotation part 400.

The rotary sphere 412 forms a friction force of a predetermined or more in the state fitted to the rotary hole 423. Therefore, the rotational position of the burner head 100 can be easily fixed.

The frictional force is the minimum force that the burner head 100 may not flow.

Again, referring to FIG. 4, when the burner head 100 is rotated at a predetermined angle, the light passing distance can be shortened, and thus a black curve having improved straightness can be obtained.

Accordingly, it is possible to accurately analyze the proportional relationship between absorbance and sample concentration, thereby enabling quantitative analysis even if the sample concentration increases.

Embodiment according to the present invention can be adjusted to a rotation angle of 15 degrees or more by adjusting the angle of rotation of the burner head to the left and right using a positioning unit.

Accordingly, the embodiment according to the present invention can eliminate the inconvenience of changing the fire by completely extinguishing the flame of the burner head and then completely separated from the spray chamber of the burner head to adjust the angle of the burner head more than 15 degrees.

Embodiments according to the present invention can efficiently reduce the analysis time by adjusting the rotation angle in real time without separate separation of the burner head.

The embodiment according to the present invention can obtain an analysis value with high reproducibility and accuracy by adjusting the angle of the burner head of 45 degrees or more without extinguishing the flame of the burner head to high concentration of elements.

In the embodiment according to the present invention, since the preparative and refraction processes may be omitted when analyzing a high concentration of elements, error factors in the sample solution may be eliminated.

100: burner head 200: rotating part
210: body 220: hook projection
300: chamber 310: hole
320: positioning hole 400: rotating part
410: first rotating part 420: second rotating part

Claims (7)

Burner head;
A rotating part provided at a lower end of the burner head;
A chamber for rotationally supporting the rotating unit; And
It includes a positioning unit for determining the rotation position of the rotating unit,
The rotating part has a circular columnar shape and has a body formed to protrude from the bottom of the burner head, the outer periphery of the body is formed with a locking projection protruding along the circumferential direction, the outer surface of the body above the locking projection Atomic absorption spectrometer, characterized in that the graduations are formed at regular intervals.
delete The method of claim 1,
The lower end of the rotating part is fitted into a hole formed in the chamber,
The locking projections are atomic absorption analysis device, characterized in that over the area around the hole.
The method of claim 3, wherein
The positioning unit,
A positioning hole penetrating the inner space of the chamber;
And a positioning bolt which is inserted into the positioning hole and pressurizes and supports the body fitted into the hole of the chamber.
The method of claim 1,
The rotation unit includes:
A first rotating part provided at a lower end of the burner head;
Rotating support of the first rotation to be rotated 360 degrees, and provided with a second rotation that is rotationally supported in the chamber,
The first rotating part,
A first body protruding from the lower end of the burner head, a connecting rod extending from the lower end of the first body, and a rotary hole formed at the lower end of the connecting rod,
The second rotating part,
It has a second body is formed to protrude from the bottom of the burner head to form a circular column shape, and provided on the upper end of the second body and the rotary support end is inserted into the rotary support end for rotating the support 360 degrees,
The outer periphery of the second body is formed with a locking projection protruding in the circumferential direction,
Atomic absorption spectrometer, characterized in that the graduation at a predetermined interval is formed on the outer surface of the second body above the locking projection.
6. The method of claim 5,
The lower end of the second rotating part is fitted into a hole formed in the chamber,
The locking projections are atomic absorption analysis device, characterized in that over the area around the hole.
The method according to claim 6,
The positioning unit,
A positioning hole penetrating the inner space of the chamber;
And a positioning bolt which is inserted into the positioning hole and pressurizes and supports the body fitted into the hole of the chamber.

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