KR102650229B1 - Apparatus for collecting kit - Google Patents

Abstract

It relates to a polonium collection kit that can efficiently collect polonium from a large volume of samples, comprising a stirring vessel containing a sample solution, and a polonium collection unit disposed within the stirring vessel to be submerged in the sample solution and collecting polonium from the sample solution. , and a heating stirrer that rotates the polonium collection unit by applying heat and magnetic force to the stirring container, and the polonium collection unit includes a metal disk provided with a collection surface on one side to collect the polonium, and accommodating the metal disk. a housing, and a fixing member coupled to the housing to fix the metal disk, wherein the housing includes a support wing having an area larger than the upper or lower area of the fixing member, and a center of the upper side of the support wing. A groove of a predetermined depth is formed in the area to accommodate the metal disk and includes a receiving portion coupled to the fixing member, and a support portion that protrudes in the longitudinal direction from one end of the lower side of the support wing to the other end to accommodate the magnetic bar. You can.

Description

Polonium collection kit {APPARATUS FOR COLLECTING KIT}

The present invention relates to a polonium collection kit, and more specifically, to a polonium collection kit that can efficiently collect polonium from a large volume of samples.

In general, the unstable nucleus of a radioactive element undergoes nuclear decay several times to become a stable nucleus, and at this time, alpha-rays, beta-rays, and gamma-rays of specific energy are emitted.

Radioactive elements can be divided into natural radionuclides that exist in nature and artificial radionuclides that are artificially created.

However, natural radionuclides and artificial radionuclides can have adverse effects on people and the environment if exposure exceeds a certain standard depending on the concentration, dose, and quality of the radioactive element.

Polonium is a radioactive element and has a total of 42 isotopes, of which 7 are natural radionuclides and are uranium and thorium decay series nuclides.

Polonium-210 is a daughter nuclide of radon-222 released into the atmosphere and can exist in all environments through dry and wet deposition.

Polonium-210 has a half-life of 138 days, emits alpha particles of 5.3 MeV, and can be converted to the stable isotope lead-206.

Polonium-210 has the property of adsorbing well on the surface of material particles, and when absorbed into the human body through drinking water, food intake, or smoking, it can accumulate in the body and cause continuous internal radiation exposure.

Because alpha particles have a short path length and weak penetrating power, alpha particles emitted from polonium-210 cannot travel far and can kill or damage cells by transferring a large amount of energy to a very close area.

For polonium analysis, alpha spectroscopic analysis is mainly used, and for alpha spectroscopic analysis, it is necessary to manufacture a measurement source in a form suitable for measurement.

Currently, various devices are being used to manufacture sources for polonium measurement, but the existing devices for producing sources for polonium measurement had the problem of being complicated to use, bulky, and expensive.

Therefore, in the future, there is a need for the development of a polonium collection kit that is simple to use, small in volume, and inexpensive, and can easily, quickly and efficiently collect polonium from large samples.

Republic of Korea Patent Publication No. 10-1974503 (April 25, 2019)

The technical problem to be achieved by an embodiment of the present invention is to increase the area of the support wing of the housing and increase the length of the support portion that accommodates the magnetic bar, so that polonium can be extracted from a large sample while being simple to use, small in volume, and inexpensive. We aim to provide a polonium collection kit that can collect polonium easily, quickly, and efficiently.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below. You will be able to.

In order to solve the above technical problem, the polonium collection kit according to an embodiment of the present invention includes a stirring vessel containing a sample solution, and is disposed within the stirring vessel to be submerged in the sample solution to collect polonium from the sample solution. A polonium collection unit, and a heating stirrer that rotates the polonium collection unit by applying heat and magnetic force to the stirring container, wherein the polonium collection unit includes a metal disk provided with a collection surface on one side to collect the polonium, the It includes a housing for accommodating a metal disc, and a fixing member coupled to the housing to fix the metal disc, wherein the housing includes a support wing having an area larger than the upper or lower area of the fixing member, and the support wing. A groove of a predetermined depth is formed in the central area of the upper side to accommodate the metal disk and a receiving portion coupled to the fixing member, and a magnetic bar protrudes longitudinally from one end of the lower side of the support wing to the other end to accommodate the magnetic bar. It may include a support.

In an alternative embodiment of the polonium collection kit, the receiving portion may include a groove having a first area, and the support vane may have a second area that is larger than the first area.

In an alternative embodiment of the polonium capture kit, the second area of the support vane may be determined depending on the lower area of the stirred vessel.

In an alternative embodiment of the polonium capture kit, the second area of the support vanes may occupy 30% to 90% of the lower area of the stirred vessel.

In an alternative embodiment of the polonium collection kit, the length of the support portion that accommodates the magnetic bar may be determined according to the second area of the support wing.

In an alternative embodiment of the polonium collection kit, the receiving portion includes a circular groove having a first diameter, the support vane has a circular shape having a second diameter longer than the first diameter, and the magnetic bar The receiving portion may have a length equal to the second diameter of the support wing.

In an alternative embodiment of the polonium collection kit, the receiving portion includes a circular groove having a first diameter, and the support wing has an elliptical shape with a major diameter and a minor diameter longer than the first diameter, The support portion that accommodates the magnetic bar may have a length equal to the major diameter of the support wing.

In an alternative embodiment of the polonium collection kit, the receiving portion includes a circular groove having a first diameter, and the support vane has a second diameter longer than the first diameter and a plurality of inclined grooves at an angle. It has a propeller shape including blades, and the support portion that accommodates the magnetic bar may have a length equal to the second diameter of the support blade.

In an alternative embodiment of the polonium collection kit, the support vanes may have a lower side area that is larger than an upper side area, and the side surfaces may be inclined.

In an alternative embodiment of the polonium collection kit, the support wing has a plurality of pickup grooves formed along the edge of the upper side, and the plurality of pickup grooves have groove edges of the receiving portion and the support wing. It can be located between edges.

In an alternative embodiment of the polonium collection kit, the support portion includes a first protruding bar that receives the magnetic bar and passes through the lower side center point of the support blade, and is relative to the first protrusion bar to pass the lower side center point of the support blade. It may include a second protruding bar disposed in a vertical direction.

In an alternative embodiment of the polonium collection kit, the length of the first protruding bar may be equal to the diameter of the support vane.

In an alternative embodiment of the polonium collection kit, the fixing member is made of a hollow shape with a through hole formed therein, and has a lower end inserted and fastened into the receiving groove of the housing and exposed to the outside of the receiving groove of the housing. The upper part of the fixing member may have a concavo-convex pattern formed on the outer peripheral surface.

In an alternative embodiment of the polonium collection kit, the heating stirrer includes a hot plate on which the stirring vessel is mounted, a heater that applies heat to the stirring vessel mounted on the hot plate, and a magnetic force to the stirring vessel mounted on the hot plate. In addition, it may include a magnet that rotates so that the polonium collection unit rotates.

The effect of the polonium collection kit according to the present invention will be described as follows.

The present invention increases the area of the support wings of the housing and increases the length of the support portion that accommodates the magnetic bar, so that polonium can be collected easily, quickly, and efficiently from a large volume of samples while being simple to use, small in volume, and inexpensive. .

Further scope of applicability of the present invention will become apparent from the detailed description that follows. However, since various changes and modifications within the spirit and scope of the present invention may be clearly understood by those skilled in the art, the detailed description and specific embodiments such as preferred embodiments of the present invention should be understood as being given only as examples.

Figure 1 is a diagram for explaining a polonium collection kit according to an embodiment of the present invention.
Figures 2 to 4 are diagrams for explaining the structure of the polonium collection unit of Figure 1.
Figure 5 is an exploded view of the polonium collection unit of Figure 1.
Figure 6 is a combined diagram of the polonium collection unit of Figure 1.
Figure 7 is a diagram for explaining a polonium collection unit according to the first embodiment of the present invention.
Figure 8 is a diagram for explaining the polonium collection unit according to the second embodiment of the present invention.
Figure 9 is a diagram for explaining the polonium collection unit according to the third embodiment of the present invention.
Figure 10 is a diagram for explaining the polonium collection unit according to the fourth embodiment of the present invention.
Figure 11 is a diagram for explaining the polonium collection unit according to the fifth embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

The suffixes “module” and “part” for the components used in the following description are simply given in consideration of the ease of writing this specification, and the “module” and “part” may be used interchangeably.

Furthermore, embodiments of the present invention will be described in detail below with reference to the accompanying drawings and the contents described in the accompanying drawings, but the present invention is not limited or limited by the embodiments.

The terms used in this specification are general terms that are currently widely used as much as possible while considering the function in the present invention, but this may vary depending on the intention or custom of a person skilled in the art or the emergence of new technology. In addition, in certain cases, there are terms arbitrarily selected by the applicant, and in this case, the meaning will be described in the description of the relevant invention. Therefore, we would like to clarify that the terms used in this specification should be interpreted based on the actual meaning of the term and the overall content of this specification, not just the name of the term.

Figure 1 is a diagram for explaining a polonium collection kit according to an embodiment of the present invention, and Figures 2 to 4 are diagrams for explaining the structure of the polonium collection unit of Figure 1.

Here, FIG. 2 is a view showing the upper part of the polonium collection unit, FIG. 3 is a view showing the lower part of the polonium collection unit, and FIG. 4 is a structural cross-sectional view along the line I-I of the polonium collection unit.

As shown in Figure 1, the polonium collection kit of the present invention is disposed in the stirring container 200 to be submerged in the sample solution (S), a stirring container 200 containing the sample solution (S), and the sample solution (S). ) It may include a polonium collection unit 100 that collects polonium from, and a heating stirrer 400 that rotates the polonium collection unit 100 by applying heat and magnetic force to the stirring container 200.

Here, the stirring container 200 is sized to accommodate the sample solution (S) and the polonium collection unit 100.

The top of the stirring container 200 may be open, and a lid 300 may be coupled to the top of the stirring container 200.

The sample solution (S) heated in the stirring container 200 may evaporate and be discharged into the open top of the stirring container 200.

The lid 300 covers the stirring container 200, thereby reducing the amount of sample solution (S) leaving the stirring container 200 or preventing the sample solution (S) from escaping from the stirring container 200. can do.

The lid 300 may have a convex central portion, or may be formed in various shapes that can cover the stirring container 200.

Next, the sample solution (S) is a solution containing polonium and can be extracted from samples collected from seawater, groundwater, river water, soil, etc.

A variety of known methods can be used to extract a polonium-containing solution from a sample. For example, a sample in a solid state is freeze-dried and freeze-ground to be pretreated by a physicochemical method to make it into a liquid state, and then the liquid sample is converted to a liquid state. By separation and purification, a polonium-containing solution can be extracted.

Known methods for extracting polonium-containing solutions include Extraction chromatographic separation, Liquid-liquid Extraction methods, and Ion Exchange chromatography.

Next, the heating stirrer 400 includes a hot plate 410 having a flat upper surface so that the stirring vessel 200 is seated, a heater (not shown) that applies heat to the stirring vessel 200 seated on the hot plate 410, And it may include a magnet (not shown) that rotates so that the polonium collection unit 100 rotates by applying magnetic force to the stirring container 200 mounted on the hot plate 410.

And, the heating stirrer 400 creates suitable conditions for the polonium contained in the sample solution (S) to attach to the metal disk 110 of FIG. 4.

That is, the heating stirrer 400 applies heat to the inside of the stirring container 200 to heat the sample solution S contained in the stirring container 200 to a preset temperature (for example, from several tens of degrees to 100 degrees or more). .

In addition, the heating stirrer 400 applies magnetic force to the inside of the stirring container 200 to rotate the polonium collection unit 100 having the magnetic bar 130 of FIG. 4 at high speed in the sample solution S. (S) can be stirred.

Next, as shown in FIGS. 2 to 4, the polonium collection unit 100 includes a metal disk 110 with a collection surface on one side to collect polonium, and a housing 120 for accommodating the metal disk 110. ), and may include a fixing member 140 that is coupled to the housing 120 and fixes the metal disk 110.

Here, the housing 120 has support wings 129 having an area larger than the upper or lower area of the fixing member 140, and a groove of a predetermined depth is formed in the central area of the upper side of the support wing 129 to form a metal A receiving portion 121 that accommodates the disk 110 and is coupled to the fixing member 140, and a support that protrudes in the longitudinal direction from one end of the lower side of the support wing 129 to the other end to accommodate the magnetic bar 130. It may include unit 126.

Additionally, the receiving portion 121 may include a groove having a first area, and the support wing 129 may have a second area that is wider than the first area.

Here, the second area of the support wing 129 may be determined according to the lower area of the stirring vessel 200.

For example, the second area of the support wing 129 may occupy about 30% to about 90% of the total lower area of the stirring vessel 200.

In this way, the reason why the second area of the support wing 129 is determined according to the lower area of the stirring vessel 200 is that the polonium collection unit 100 can be rotated stably at high speed even in the large-capacity stirring vessel 200, thereby increasing the large capacity. This is to collect a large amount of polonium from the sample solution in a short time.

Additionally, the length of the support portion 126 that accommodates the magnetic bar 130 may be determined according to the second area of the support wing 129.

The reason is that when the second area of the support wing 129 increases, the length of the support portion 126 that accommodates the magnetic bar 130 is correspondingly increased, so that when the polonium collection unit 100 is rotated at high speed, This is to ensure that the polonium collection unit 100 does not deviate from its original position and rotates stably and at high speed in the same position.

As an example, the housing 120 of the polonium collection unit 100 includes the receiving portion 121 having a circular groove having a first diameter, and the support wing 129 having a second diameter longer than the first diameter. The support portion 126, which has a circular shape and accommodates the magnetic bar 130, may have a length equal to the second diameter of the support wing 129.

As another example, the housing 120 of the polonium collection unit 100 includes the receiving portion 121 having a circular groove having a first diameter, and the support wing 129 having a long diameter longer than the first diameter and a short diameter. It has an oval shape with a diameter, and the support portion 126 that accommodates the magnetic bar 130 may have a length equal to the long diameter of the support wing 129.

As another example, the housing 120 of the polonium collection unit 100 includes a circular groove in which the receiving portion 121 has a first diameter, and the support wing 129 has a second diameter longer than the first diameter. It has a propeller shape including a plurality of blades inclined at a certain angle, and the support portion 126 that accommodates the magnetic bar 130 may have a length equal to the second diameter of the support blade 129.

As such, the present invention can modify the shape of the support wing 129 in various ways so that the sample solution can be quickly stirred when the polonium collection unit 100 rotates at high speed.

As another example, the support wings 129 may be separated into multiple pieces, and each support wing 129 may be separated from the housing 120 or mounted on the housing 120.

Next, the support wing 129 may have a lower side area that is larger than the upper side area, and the side surface may be inclined.

For example, the support wing 129 may have an acute angle between the side and the lower side, and an obtuse angle between the side and the upper side.

The reason is that when the polonium collection unit 100 is rotated at high speed, the polonium collection unit 100 does not deviate from its original position and rotates stably at high speed in the same position.

In some cases, the support wing 129 has a plurality of pickup grooves 122 formed along the edge of the upper side, and the plurality of pickup grooves 122 are supported by the groove edge of the receiving portion 121. It may be located between the edges of the wings 129.

Here, the reason for forming the pickup groove 122 in the support wing 129 is when the polonium collection unit 100 is placed in the stirring container 200 or the polonium collection unit 100 is taken out from the stirring container 200. , This is to make it easy to pick it up using instruments such as tweezers.

Next, the receiving portion 121 may be provided with a housing screw portion on the inner peripheral surface of the groove and fastened to the fixing member screw portion formed on the outer peripheral surface of the fixing member 140.

Also, the groove area of the receiving portion 121 may be larger than the area of the metal disk 110.

Here, the groove area of the receiving portion 121 may be determined according to the area of the metal disk 110.

As an example, the present invention increases the groove area of the receiving part 121 when the area of the metal disk 110 increases, and reduces the groove area of the receiving part 121 when the area of the metal disk 110 decreases. You can.

The reason is to stably fix the metal disk 110 and to ensure that the collection of polonium is concentrated on the metal disk 110.

Additionally, the groove shape of the receiving portion 121 may be determined depending on the shape of the metal disk 110.

For example, the groove shape of the receiving portion 121 may have the same circular shape as the shape of the metal disk 110 when the shape of the metal disk 110 is circular, or the shape of the metal disk 110 may be polygonal. When , it may have a polygonal shape identical to that of the metal disk 110.

Next, the thickness of the support portion 126 may be determined according to the thickness of the magnetic bar 130.

As an example, in the present invention, when the thickness of the magnetic bar 130 increases, the thickness of the support portion 126 can be increased, and when the thickness of the magnetic bar 130 decreases, the thickness of the support portion 126 can be reduced. .

The reason is to stably accommodate the magnetic bar 130.

Additionally, the thickness of the support portion 126 may be thicker than the thickness of the support wing 129.

The reason is to rotate the polonium collection unit 100 stably and at high speed.

In addition, the support portion 126 includes a first protruding bar 126a that accommodates the magnetic bar 130 and passes through the center point of the lower side of the support wing 129, and a first protruding bar 126a that passes through the center point of the lower side of the support wing 129. It may include a second protruding bar 126b disposed in a direction perpendicular to the first protruding bar 126a.

Here, the length of the first protruding bar 126a may be the same as the diameter of the support wing 129.

And, the length of the second protruding bar 126b may be the same as the length of the first protruding bar 126a.

At this time, the support wing 129 may be circular.

In some cases, the length of the second protruding bar 126b may be shorter than the length of the first protruding bar 126a.

At this time, the support wing 129 may have an oval shape.

Next, the thickness of the second protruding bar 126b may be the same as the thickness of the first protruding bar 126a.

In addition, the first and second protruding bars 126a and 126b have inclined sides at both ends, and the upper area in contact with the support wing 129 may be narrower than the lower area in contact with the stirring container 200. .

The reason is to rotate the polonium collection unit 100 stably and at high speed.

In addition, the support portion 126 includes a first protruding bar 126a that accommodates the magnetic bar 130 and passes through the center point of the lower side of the support wing 129, and a first protruding bar 126a that passes through the center point of the lower side of the support wing 129. It may further include a second protrusion bar 126b disposed in a direction perpendicular to the first protrusion bar 126a, and a third protrusion bar disposed between the first protrusion bar 126a and the second protrusion bar 126b. there is.

Here, the length of the third protruding bar may be the same as the length of the first protruding bar.

At this time, the support wing 129 may be circular.

In some cases, the length of the third protruding bar may be shorter than the length of the first protruding bar and may be longer than the length of the second protruding bar.

At this time, the support wing 129 may have an oval shape.

And, the thickness of the third protruding bar may be the same as the thickness of the first protruding bar and the second protruding bar.

In addition, the sides of both ends of the third protruding bar are inclined, and the upper area in contact with the support wing 129 may be narrower than the lower area in contact with the stirring container 200.

The reason is to rotate the polonium collection unit 100 stably and at high speed.

Next, the fixing member 140 is made of a hollow shape with a through hole formed therein, and has a lower end that is inserted and fastened into the groove of the receiving part 121 of the housing 120, and a receiving part 121 of the housing 120. It may include an upper part exposed to the outside of the groove.

Here, the lower end of the fixing member 140 may have a fixing member screw portion formed on the outer peripheral surface and be fastened to the housing screw portion provided on the inner peripheral surface of the groove of the receiving portion 121 of the housing 120.

At this time, when the lower end of the fixing member 140 is fastened to the housing screw portion, it contacts the edge of the metal disk 110 accommodated in the groove of the receiving portion 121 of the housing 120 and presses the metal disk 110 in the downward direction. can do.

Additionally, an uneven pattern 128 may be formed on the outer peripheral surface of the upper end of the fixing member 140.

The reason is that when the user fastens the fixing member 140 to the groove of the receiving part 121 of the housing 120, friction is provided to prevent it from slipping from the user's hand so that the user can easily fasten it.

Next, the metal disk 110 may be formed in a disc shape, but this is only an example and is not limited thereto.

Additionally, a collection surface to which polonium is attached may be provided on one side of the metal disk 110.

Here, the collection surface may be preferably polished to be uniform and smooth.

The reason is that the emission direction of alpha particles emitted from polonium collected on a smooth, polished collection surface appears relatively uniform, but the emission direction of alpha particles emitted from polonium collected on a bumpy and rough collection surface appears relatively uniform. This is because it is bound to be uneven.

Therefore, the smoothly polished collection surface can be advantageous in increasing the measurement efficiency and measurement accuracy of polonium in the process of measuring polonium collected on the metal disk 110 using an alpha ray measuring device.

Additionally, a cover may be attached to the other surface of the metal disk 110.

Here, the cover covers the other side of the metal disk 110 and can prevent polonium from adhering to the other side of the metal disk 110.

The reason for attaching the cover is that if some of the polonium contained in the sample solution adheres to the other surface of the metal disk 110, a problem may occur in which the measurement accuracy of the amount of polonium contained in the sample solution is reduced.

The metal disk 110 may be made of various metals that can collect polonium, such as silver, aluminum, nickel, stainless steel, and copper.

In addition to the disk shape as shown, the metal disk 110 can be changed into various other shapes with a collection surface on one side to which polonium can be attached.

Next, the housing 120 may be made of the same material as the fixing member 140.

For example, the housing 120 and the fixing member 140 may be made of Teflon resin or various other plastic materials with a low coefficient of friction.

Additionally, a magnetic bar 130 is disposed inside the support portion 126 of the housing 120. The magnetic bar 130 may be shaped like a bar shorter than the length of the support portion 126.

In addition, the magnetic bar 130 can be insert-molded with the housing 120, and by embedding the magnetic bar 130 in the housing 120, the housing 120 is exposed to the magnetic force generated by the heating stirrer 400. It can be rotated by

The housing 120 may be changed to various other structures capable of accommodating the metal disk 110 in addition to the structure shown.

Additionally, various other methods other than the insert injection method may be used to connect the housing 120 and the magnetic bar 130.

As such, the present invention increases the area of the support wings of the housing and increases the length of the support portion that accommodates the magnetic bar, so that polonium can be collected easily, quickly, and efficiently from a large volume of samples while being simple to use, small in volume, and inexpensive. You can.

Figure 5 is an exploded view of the polonium collection unit of Figure 1, and Figure 6 is a combined view of the polonium collection unit of Figure 1.

As shown in Figures 5 and 6, the polonium collection unit of the present invention includes a metal disk 110 on one side of which a collection surface 111 is provided to collect polonium, and a housing for accommodating the metal disk 110 ( 120), and may include a fixing member 140 that is coupled to the housing 120 and fixes the metal disk 110.

Here, a collection surface 111 to which polonium is attached is provided on one side of the metal disk 110, and the collection surface 111 can be polished to be homogeneous and smooth in order to increase the measurement efficiency and measurement accuracy of polonium. .

Next, a cover 112 may be attached to the other surface of the metal disk 110.

The cover 112 covers the other surface of the metal disk 110 and prevents polonium from adhering to the other surface of the metal disk 110, thereby increasing the measurement accuracy of the amount of polonium.

Next, the housing 120 includes support wings 129 having an area larger than the upper or lower area of the fixing member 140, and a groove of a predetermined depth is formed in the central area of the upper side of the support wing 129 to form a metal A receiving portion 121 that accommodates the disk 110 and is coupled to the fixing member 140, and a support that protrudes in the longitudinal direction from one end of the lower side of the support wing 129 to the other end to accommodate the magnetic bar 130. It may include unit 126.

Additionally, the receiving portion 121 may include a groove having a first area, and the support wing 129 may have a second area that is wider than the first area.

Here, the second area of the support wing 129 may be determined according to the lower area of the stirring vessel.

For example, the second area of the support wing 129 may occupy about 30% to about 90% of the total lower area of the stirring vessel.

In this way, the reason why the second area of the support wing 129 is determined according to the lower area of the stirring vessel is that the polonium collection unit can be rotated stably at high speed even in a large-capacity stirring vessel, so a large amount of sample solution can be collected in a short time. This is to capture polonium.

Additionally, the length of the support portion 126 that accommodates the magnetic bar 130 may be determined according to the second area of the support wing 129.

The reason is that when the second area of the support wing 129 increases, the length of the support portion 126 that accommodates the magnetic bar 130 is correspondingly increased, so that when the polonium collection unit is rotated at high speed, the polonium collection unit This is to ensure that it rotates stably and at high speed in the same position without deviating from this fixed position.

Additionally, the accommodating part 121 may have a receiving space 122 in which the metal disk 110 is accommodated, and a flat mounting surface 123 that supports the metal disk 110.

Next, the receiving portion 121 may be provided with a housing screw portion 124 on the inner peripheral surface of the groove and fastened to the fixing member screw portion 142 formed on the outer peripheral surface of the fixing member 140.

Also, the groove area of the receiving portion 121 may be larger than the area of the metal disk 110.

Here, the groove area of the receiving portion 121 may be determined according to the area of the metal disk 110.

As an example, the present invention increases the groove area of the receiving part 121 when the area of the metal disk 110 increases, and reduces the groove area of the receiving part 121 when the area of the metal disk 110 decreases. You can.

The reason is to stably fix the metal disk 110 and to ensure that the collection of polonium is concentrated on the metal disk 110.

Additionally, the groove shape of the receiving portion 121 may be determined depending on the shape of the metal disk 110.

For example, the groove shape of the receiving portion 121 may have the same circular shape as the shape of the metal disk 110 when the shape of the metal disk 110 is circular, or the shape of the metal disk 110 may be polygonal. When , it may have a polygonal shape identical to that of the metal disk 110.

Next, the thickness of the support portion 126 may be determined according to the thickness of the magnetic bar 130.

As an example, in the present invention, when the thickness of the magnetic bar 130 increases, the thickness of the support portion 126 can be increased, and when the thickness of the magnetic bar 130 decreases, the thickness of the support portion 126 can be reduced. .

The reason is to stably accommodate the magnetic bar 130.

Additionally, the thickness of the support portion 126 may be thicker than the thickness of the support wing 129.

The reason is to rotate the polonium collection unit 100 stably and at high speed.

Next, the fixing member 140 is made of a hollow shape with a through hole 141 formed therein, and has a lower end that is inserted and fastened into the groove of the receiving part 121 of the housing 120, and a receiving part of the housing 120. (121) It may include an upper part exposed to the outside of the groove.

Here, the lower end of the fixing member 140 may be formed with a fixing member screw portion 142 on the outer peripheral surface and fastened to the housing screw portion 124 provided on the inner peripheral surface of the groove of the receiving portion 121 of the housing 120.

At this time, when the lower end of the fixing member 140 is fastened to the housing screw portion 124, it contacts the edge of the metal disk 110 accommodated in the groove of the receiving portion 121 of the housing 120 to lower the metal disk 110. It can be pressurized in either direction.

Additionally, the upper end of the fixing member 140 may have a concavo-convex pattern formed on the outer peripheral surface.

The reason is that when the user fastens the fixing member 140 to the groove of the receiving part 121 of the housing 120, friction is provided to prevent it from slipping from the user's hand so that the user can easily fasten it.

Figure 7 is a diagram for explaining the polonium collection unit according to the first embodiment of the present invention.

As shown in Figure 7, the polonium collection unit according to the first embodiment of the present invention may include a housing for accommodating a metal disk and a fixing member 140 that is coupled to the housing and fixes the metal disk. , a support wing 129 having an area larger than the upper or lower area of the fixing member 140, and a groove of a predetermined depth is formed in the central area of the upper side of the support wing 129 to accommodate the metal disk and secure the fixing member ( 140), and may include a support portion 126 that protrudes in the longitudinal direction from one end of the lower side of the support wing 129 to the other end to accommodate the magnetic bar 130.

Here, in the housing of the polonium collection unit, when the support wing 129 is circular and the fixing member 140 is circular, the diameter of the support wing 129 is longer than the diameter of the fixing member 140, and the magnetic bar ( The support portion 126 that accommodates 130 may have a length equal to the diameter of the support wing 129.

In some cases, the support wing 129 may have a lower side area that is larger than the upper side area and a side surface that may be inclined.

For example, the support wing 129 may have an acute angle between the side and the lower side, and an obtuse angle between the side and the upper side.

The reason is that when rotating the polonium collection unit at high speed, the polonium collection unit does not deviate from its fixed position and rotates stably at high speed in the same position.

In addition, the support portion 126 includes a first protruding bar 126a that accommodates the magnetic bar 130 and passes through the center point of the lower side of the support wing 129, and a first protruding bar 126a that passes through the center point of the lower side of the support wing 129. It may include a second protruding bar 126b disposed in a direction perpendicular to the first protruding bar 126a.

Here, the length L1 of the first protruding bar 126a may be equal to the diameter of the support wing 129.

And, the length L2 of the second protruding bar 126b may be equal to the length L1 of the first protruding bar 126a.

Figure 8 is a diagram for explaining the polonium collection unit according to the second embodiment of the present invention.

As shown in Figure 8, the polonium collection unit according to the second embodiment of the present invention may include a housing accommodating a metal disk and a fixing member coupled to the housing to fix the metal disk. The housing is a fixing member. A support wing 129 having an area larger than the upper or lower area of the support wing 129, a groove of a predetermined depth is formed in the central area of the upper side of the support wing 129 to accommodate the metal disk and a receiving portion coupled to the fixing member, and The lower side of the support wing 129 may include a support portion 126 that protrudes in the longitudinal direction from one end to the other end and accommodates the magnetic bar 130.

Here, in the housing of the polonium collection unit, when the support wing 129 is oval and the fixing member is circular, the major and minor diameters of the support wing 129 are longer than the diameter of the fixing member, and the magnetic bar 130 The support portion 126 that accommodates may have a length equal to the long diameter of the support wing 129.

In some cases, the support wing 129 may have a lower side area that is larger than the upper side area and a side surface that may be inclined.

For example, the support wing 129 may have an acute angle between the side and the lower side, and an obtuse angle between the side and the upper side.

The reason is that when rotating the polonium collection unit at high speed, the polonium collection unit does not deviate from its fixed position and rotates stably at high speed in the same position.

In addition, the support portion 126 includes a first protruding bar 126a that accommodates the magnetic bar 130 and passes through the center point of the lower side of the support wing 129, and a first protruding bar 126a that passes through the center point of the lower side of the support wing 129. It may include a second protruding bar 126b disposed in a direction perpendicular to the first protruding bar 126a.

Here, the length L1 of the first protruding bar 126a may be equal to the diameter of the support wing 129.

Additionally, the length L2 of the second protruding bar 126b may be shorter than the length L1 of the first protruding bar 126a.

Figure 9 is a diagram for explaining a polonium collection unit according to a third embodiment of the present invention.

As shown in Figure 9, the polonium collection unit according to the third embodiment of the present invention may include a housing accommodating a metal disk and a fixing member coupled to the housing to fix the metal disk. The housing is a fixing member. A support wing 129 having an area larger than the upper or lower area of the support wing 129, a groove of a predetermined depth is formed in the central area of the upper side of the support wing 129 to accommodate the metal disk and a receiving portion coupled to the fixing member, and The lower side of the support wing 129 may include a support portion 126 that protrudes in the longitudinal direction from one end to the other end and accommodates the magnetic bar 130.

Here, the housing of the polonium collection unit has a propeller-shaped support wing 129, and when the fixing member is circular, the diameter of the support wing 129 is longer than the diameter of the fixing member, and accommodates the magnetic bar 130. The support portion 126 may have a length equal to the diameter of the support wing 129.

In some cases, the support wing 129 may have a lower side area that is larger than the upper side area and a side surface that may be inclined.

For example, the support wing 129 may have an acute angle between the side and the lower side, and an obtuse angle between the side and the upper side.

The reason is that when rotating the polonium collection unit at high speed, the polonium collection unit does not deviate from its fixed position and rotates stably at high speed in the same position.

In addition, the support portion 126 includes a first protruding bar 126a that accommodates the magnetic bar 130 and passes through the center point of the lower side of the support wing 129, and a first protruding bar 126a that passes through the center point of the lower side of the support wing 129. It may include a second protruding bar 126b disposed in a direction perpendicular to the first protruding bar 126a.

Here, the length L1 of the first protruding bar 126a may be equal to the diameter of the support wing 129.

And, the length L2 of the second protruding bar 126b may be equal to the length L1 of the first protruding bar 126a.

Figure 10 is a diagram for explaining the polonium collection unit according to the fourth embodiment of the present invention.

As shown in Figure 10, the housing 120 of the polonium collection unit according to the fourth embodiment of the present invention includes support wings 129 and support wings 129 having an area larger than the upper or lower area of the fixing member. ) may include a support portion 126 that protrudes in the longitudinal direction from one end of the lower side to the other end and accommodates the magnetic bar 130.

Here, the support portion 126 has inclined sides at both ends, and the upper area in contact with the support wing 129 may be narrower than the lower area in contact with the stirring container.

The reason is to rotate the polonium collection unit stably and at high speed.

That is, the support portion 126 may have a lower side area that is larger than the upper side area, and the side surface may be inclined.

For example, the support portion 126 may have an acute angle between the side and the lower side, and an obtuse angle between the side and the upper side.

The reason is that when rotating the polonium collection unit at high speed, the polonium collection unit does not deviate from its fixed position and rotates stably at high speed in the same position.

Figure 11 is a diagram for explaining the polonium collection unit according to the fifth embodiment of the present invention.

As shown in Figure 11, the housing 120 of the polonium collection unit according to the fourth embodiment of the present invention includes support wings 129 and support wings 129 having an area larger than the upper or lower area of the fixing member. ) may include a support portion 126 that protrudes in the longitudinal direction from one end of the lower side to the other end and accommodates the magnetic bar 130.

Here, the support portion 126 includes a first protruding bar 126a that accommodates the magnetic bar 130 and passes the center point of the lower side of the support wing 129, and a first protruding bar 126a that passes the center point of the lower side of the support wing 129. 1 A second protrusion bar 126b disposed in a direction perpendicular to the protrusion bar 126a, and a third protrusion bar 126c disposed between the first protrusion bar 126a and the second protrusion bar 126b. It can be included.

Here, the length of the third protruding bar 126c may be the same as the length of the first protruding bar 126a.

At this time, the support wing 129 may be circular.

In some cases, the length of the third protruding bar 126c may be shorter than the length of the first protruding bar 126a and longer than the length of the second protruding bar 126b.

At this time, the support wing 129 may have an oval shape.

And, the thickness of the third protruding bar 126c may be the same as the thickness of the first protruding bar 126a and the second protruding bar 126b.

In addition, the third protruding bar 126c may have inclined sides at both ends, and the upper area in contact with the support wing 129 may be narrower than the lower area in contact with the stirring container.

The reason is to rotate the polonium collection unit stably and at high speed.

As such, the present invention increases the area of the support wings of the housing and increases the length of the support portion that accommodates the magnetic bar, so that polonium can be collected easily, quickly, and efficiently from a large volume of samples while being simple to use, small in volume, and inexpensive. You can.

The features, structures, effects, etc. described in the present inventions above are included in at least one embodiment of the present invention, and are not necessarily limited to only one embodiment. Furthermore, the features, structures, effects, etc. illustrated in each embodiment can be combined or modified and implemented in other embodiments by a person with ordinary knowledge in the field to which the embodiments belong. Therefore, contents related to such combinations and modifications should be construed as being included in the scope of the present invention.

In addition, although the above description has been made focusing on the examples, this is only an example and does not limit the present invention, and those skilled in the art will understand the above examples without departing from the essential characteristics of the present embodiment. You will be able to see that various modifications and applications are possible. For example, each component specifically shown in the examples can be modified and implemented. And these variations and differences in application should be construed as being included in the scope of the present invention as defined in the appended claims.

100: polonium collection unit 110: metal disk
111: collection surface 112: cover
120: Housing 121: Receiving part
126: support 129: support wing
130: magnetic bar 140: fixing member
200: stirring container 300: lid
400: Heating stirrer

Claims (10)

A stirred vessel containing a sample solution;
A polonium collection unit disposed within the stirring vessel to be immersed in the sample solution to collect polonium from the sample solution; and,
It includes a heating stirrer that rotates the polonium collection unit by applying heat and magnetic force to the stirring container,
The polonium collection unit,
A metal disk provided with a collection surface on one side to collect the polonium;
a housing accommodating the metal disk; and,
It includes a fixing member coupled to the housing to secure the metal disk,
The housing is,
a support wing having an area larger than the upper or lower area of the fixing member;
A groove of a predetermined depth is formed in the central area of the upper side of the support wing to accommodate the metal disk, and a receiving portion coupled to the fixing member; and,
A polonium collection kit comprising a support portion that protrudes in the longitudinal direction from one end of the lower side of the support wing to the other end and accommodates a magnetic bar. According to claim 1,
The receiving part is,
comprising a groove having a first area,
The support wings are,
A polonium collection kit, characterized in that it has a second area that is wider than the first area. According to clause 2,
The second area of the support wing is,
Polonium collection kit, characterized in that determined according to the lower area of the stirring vessel. According to clause 3,
The second area of the support wing is,
A polonium collection kit, characterized in that it occupies 30% to 90% of the lower area of the stirring vessel. According to clause 2,
The length of the support portion that accommodates the magnetic bar is,
Polonium collection kit, characterized in that determined according to the second area of the support wing. According to claim 1,
The support wings are,
A plurality of pickup grooves are formed along the edge of the upper side,
The plurality of pickup grooves are,
Polonium collection kit, characterized in that located between the edge of the groove of the receiving portion and the edge of the support wing. According to claim 1,
The base,
a first protruding bar that accommodates the magnetic bar and passes through the center point of the lower side of the support wing; and,
Polonium collection kit comprising a second protruding bar disposed in a direction perpendicular to the first protruding bar so as to pass through the center point of the lower side of the support wing. According to clause 7,
The length of the first protruding bar is,
Polonium collection kit, characterized in that the diameter of the support wing is the same. According to claim 1,
The fixing member is,
It is made of a hollow shape with a through hole formed inside,
It includes a lower part that is inserted and fastened into the receiving groove of the housing, and an upper part that is exposed to the outside of the receiving groove of the housing,
The upper part of the fixing member is,
A polonium collection kit characterized by an uneven pattern formed on the outer peripheral surface. According to claim 1,
The heating stirrer,
A hot plate on which the stirring vessel is seated;
a heater that applies heat to the stirring vessel mounted on the hot plate; and,
A polonium collection kit comprising a magnet that rotates so that the polonium collection unit rotates by applying magnetic force to the stirring vessel mounted on the hot plate.

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