KR101346662B1 - zinc ion concentration measuring kit and the measuring method using thereof - Google Patents

Abstract

The present invention relates to a zinc (Zn, Zinc) concentration detection method and detection kit, more specifically, cyclohexanone solution (Zy, Zinc) solution and zinc reagent (Zinc) in a sample containing zinc (Zn, Zinc) to be measured Refers to a method of calculating zinc (Zn, Zinc) concentration using a reagent).
The present invention is a reagent used to detect zinc ion concentration, borate (Borate), Zincon monosodium salt (2-carboxy-2 '-hydroxy-5' sulfoformyl-benzene sodium salt), boron oxide, A zinc reagent obtained by mixing ascorbate and cyanide is provided.
In the present invention, the borate is potassium metaborate KBO ₂ , metaborate such as sodium metaborate NaBO ₂ , boric acid tetraborate such as Na ₂ B ₄ O ₇ · 10H ₂ O, KB ₅ O ₈ · 4H ₂ O One or two or more of a pentaborate, boron peroxide or hypoborate is used, and boron oxide is a mixture of one or two or more of boron dioxide, diboron trioxide, tetraboron trioxide or tetraboron pentoxide, and ascorbate. Silver sodium ascorbate, potassium cyanide, potassium cyanide, interfering agent blocking agent, cyclopentanone solution, cycloheptanone solution, cyclohexanone solution or cyclohexanol solution It provides a zinc reagent, characterized in that for use in mixing.
In another aspect, the present invention further comprises a mixture of one or two or more of a cyclopentanone solution, a cycloheptanone solution, a cyclohexanone solution, or a cyclohexanol solution as a blocker blocker. Provide a detection kit.
In another aspect, the present invention provides a method of mixing the above-described interference blocking agent and zinc reagent in a sample to develop a color, the method of measuring the zinc ion concentration using the absorbance method or the colorimetric contrast method of the sample is formed.

Description

Zinc concentration measurement kit and the measuring method using the same

The present invention relates to a zinc (Zn, Zinc) concentration detection method and detection kit, more specifically, cyclohexanone solution (Zy, Zinc) solution and zinc reagent (Zinc) in a sample containing zinc (Zn, Zinc) to be measured Refers to a method of calculating zinc (Zn, Zinc) concentration using a reagent).

Recently, as environmental regulations on pollution sources such as zinc, nitrogen and phosphorus contained in water purification plants, river waters, lakes and wastewaters are tightened, various types of water quality measurements are being performed on water purification plants, effluents or river waters. In addition to the basic requirements to ensure precision and reproducibility, the characteristics required for water quality measurement should be fast, convenient, environmentally friendly and economical.

In particular, zinc is a zinc group element belonging to the 4th cycle of group 12 of the periodic table. The element symbol is Zn, the atomic weight is 65.38 g / mol, the melting point is 419.5 ° C, the boiling point is 907 ° C, and the density is 7.14g / cm3. It is a blue-white metal that exists as a divalent cation in living organisms. It is an essential inorganic material and essential element for the metabolism of living things.

However, excessive ingestion of zinc can lead to mineral imbalances, which can be a risk for human health. In terms of water quality, zinc concentration is an important subject for management.

Zinc is usually measured by an absorbance method called the Jincon method as described below.

1. Measuring principle

The principle of measurement was to measure the absorbance of the blue chelate compound produced by reacting zinc ion with gincon (2-carboxy-2'-hydroxy-5 'sulfoformyl-benzene, sodium salt) at pH ˜9 at 620 nm. How to measure. Quantification ranged from 0.002 to 0.04 mg with standard deviation of 10 to 3%.

2. Appliances and Appliances

Photophotometer or photospectrometer

3. Test method

(1) Test method

Take an appropriate amount of the pretreated sample (containing 0.04 mg or less as zinc) into a 100 ml beaker, add 6 N hydrochloric acid or 6 N sodium hydroxide solution dropwise, and neutralize it to pH 7. Then transfer to a 50 ml volumetric flask and add water. 30 ml is used.

Add 0.5 g of sodium ascorbate, 1 ml of 1% potassium cyanide solution, and shake well.

Next, add 5 ml of potassium chloride, sodium hydroxide buffer (pH 9.0), 3 ml of gincon solution, 3 ml of catcher chlorine solution (10W / V%), shake, add water, fill the mark, and fill for 2 to 5 minutes at 30 ℃ or lower. Leave to stand (Note 2) to prepare a sample solution.

Separately, 30 ml of water is tested according to the following test procedure, and the test solution is used as the blank test solution.

Using the blank test solution as a control solution, transfer the absorber to a layer-length 10 mm absorbance cell, measure the absorbance of the sample solution at 620 nm, calculate the amount of zinc from the calibration curve prepared in advance, and calculate the concentration (mg / L).

(2) Preparation of calibration curve

Take 1 ~ 20ml of zinc standard solution (0.002mg Zn / mL) step by step, put it into a 50ml volumetric flask, add water to make about 30ml, and test according to the following test method. Write.

The absorption spectrophotometry of zinc by the conventional zinc measurement method (Jincon method) has the following problems.

Said sodium ascorbate is not added when bivalent manganese does not coexist.

In addition, the degree of color development by the Jincon method is 15 ~ 29 ℃, pH is well in the range of 8.8 ~ 9.2, there is a problem that the error rate can be increased beyond this range.

In addition, the presence of potassium cyanide and heavy metal ions which do not form a complex compound in the sample coarsens and interferes with color development, thus degrading the accuracy of the measurement.

Therefore, there is a hassle to perform the following subsidiary procedure as a method used when such an interfering ion exists.

First, take 10 ml of the pretreated sample into two 100 ml idler beakers A and B, and test the idler beaker A according to the 2.4 test method.

B beaker is placed in 3 ml of water instead of 3 ml of catcher chloride solution, and tested according to 2.4 Test Method to make Sample Solution II.

Separately, water containing no zinc is tested according to the Gincon Test Method described above to make a blank test solution. Using the blank test solution as a control solution, the absorbance cell was measured at 10 mm in layer length, and the absorbance of Sample Solution I and Sample Solution II was measured at 620 nm. The amount of zinc is calculated and the concentration (mg / L) is calculated.

The present invention is an advanced zinc measurement method that solves the problems caused by the conventional Jincon method,

It is intended to provide a reagent, a detection kit, and a zinc detection method that can accurately measure zinc concentration regardless of the presence of divalent manganese in a sample.

It is also an object of the present invention to provide zinc concentration detection kits, reagents and zinc detection methods that are not significantly affected by temperature and pH.

In particular, it is an object of the present invention to provide a reagent, a detection kit, and a zinc detection method capable of accurately measuring zinc concentrations even when various interference ions coexist.

In addition, it is intended to provide reagents, detection kits and zinc detection methods that can significantly simplify zinc concentration measurement test procedures.

In order to solve the above problems,

Borate, Zincon monosodium salt (2-carboxy-2 '-hydroxy-5' sulfoformyl-benzene sodium salt), boron oxide, ascorbin A zinc reagent is prepared by mixing an acid salt (ascorbate) and a cyanide.

In the present invention, the borate is potassium metaborate KBO ₂ , metaborate such as sodium metaborate NaBO ₂ , boric acid tetraborate such as Na ₂ B ₄ O ₇ · 10H ₂ O, KB ₅ O ₈ · 4H ₂ O One or two or more of a pentaborate, boron peroxide or hypoborate is used, and boron oxide is a mixture of one or two or more of boron dioxide, diboron trioxide, tetraboron trioxide or tetraboron pentoxide, and ascorbate. It provides a zinc reagent characterized by using sodium ascorbate and cyanide using potassium cyanide.

In another aspect, the present invention further comprises a cyclopentanone solution, a cycloheptanone solution, a cyclohexanone solution, a cyclohexanone solution, or a cyclohexanol solution, further comprising a mixture of one or two or more of a blocker blocker. Provided is an ion concentration detection kit.

In another aspect, the present invention provides a method of mixing the above-mentioned interference blocking agent and zinc reagent in a sample to develop a color, the method of measuring the zinc ion concentration using the absorbance method or colorimetric contrast method of the sample is formed.

When using zinc reagents or detection kits or detection methods for zinc ion detection measurements according to the invention,

When bivalent manganese is present in the sample, a separate treatment with an interference removing reagent is required when the bivalent manganese is present in the sample, but the present invention does not require such a separate procedure.

In addition, the conventional ion measurement method requires a pretreatment process to remove the influence of the interference ions, but the present invention does not require such a pretreatment process, thereby simplifying the measurement procedure.

In addition, the zinc ion concentration detection method according to the present invention has an effect that is little affected by the temperature and PH.

In particular, the present invention exhibits an effect that the interference ions are hardly affected even when various interference ions coexist.

In addition, when zinc ions are measured using the zinc reagent or / and detection kit according to the present invention, an effect of significantly reducing the color reaction time with the sample is obtained.

1 is a calibration line quantifying the standard solution containing zinc ions in the absorbance method using a zinc ion detection kit according to the present invention.

Hereinafter, the present invention will be described in detail.

The present invention provides a reagent, a detection kit, or a detection method capable of measuring the concentration of zinc ions in a sample.

Cyclohexanone (Cyclohexanone) in a sample containing zinc (Zn, Zinc) to be measured in a sample containing zinc ions, using the absorbance spectrophotometric method as a method for detecting the concentration of zinc ions of the present invention Solution) and zinc reagent (Zinc reagent) to calculate the zinc (Zn, Zinc) concentration.

Zinc reagent of the present invention is borate (Borate), Zincon monosodium salt (2-carboxy-2 '-hydroxy-5' sulfoformyl-benzene sodium salt), boron oxide, ascor It includes ascorbate and cyanide.

Accordingly, the present invention provides a zinc detection reagent and detection kit comprising the zinc reagent composition described above.

The zinc reagent powder is 100 parts by weight of borate, 0.01 to 0.5 parts by weight of Zincon monosodium salt, 20 to 60 parts by weight of boron oxide, 20 to 60 parts by weight of ascorbate, 10 to 30 cyanide It is preferable to prepare by weight mixing.

The borate salt of the present invention is a salt of oxygen acid having boron as its central atom. Borate has anhydrous salt and hydrous salt, and both can be used.

The borate salt of the present invention is a metabolic acid such as potassium metaborate KBO ₂ , sodium metaborate NaBO ₂ , tetraborate such as borax Na ₂ B ₄ O ₇ · 10H ₂ O and pentaborate such as KB ₅ O ₈ · 4H ₂ O Can be used. In addition, peroxide or hypoborate can be used.

In the present invention, one or two or more of the above borate salts may be mixed.

In the present invention, it is preferable to use potassium borate. Potassium borate has the effect of making the sensitivity higher in measuring zinc ions.

In addition, Zincon monosodium salt (Zincon monosodium salt) of the present invention means "2-carboxy-2 '-hydroxy-5' sulfoformyl-benzene sodium salt" chelate reacted with zinc ions to develop color To produce a compound.

Boron oxide of the present invention may be used as a compound of boron and oxygen by mixing one or two or more of boron dioxide, diboron trioxide, tetraboron trioxide, tetraboron pentoxide and the like.

Ascorbate salt of the present invention is a metal ion bonded to ascorbic acid, and may be in any form in which an alkali metal or alkaline earth metal is bonded. Preferably, the present invention preferably uses sodium ascorbate. Sodium ascorbate reduces the ions that interfere with the measurement of zinc ions, thereby making accurate zinc ion concentration measurements.

The cyanide of the present invention may be used as a hydrogen cyanide salt compound by mixing any one or two or more of an alkali metal cyanide salt or an alkali cyanide metal salt.

In the present invention, the use of potassium cyanide preferably serves to increase the sensitivity of the zinc ion measurement.

The present invention provides a zinc reagent, which is the composition described above, as a reagent for measuring zinc ions in a sample.

In another aspect, the present invention provides a zinc detection reagent and detection kit comprising a blocking agent blocker in the above zinc reagent.

Interfering agent blockers of the present invention refer to chemicals that function to eliminate the effects of cations or / and anions that interfere with the detection of zinc ions.

Therefore, conventional blocker blockers that block factors that interfere with zinc ion detection can be used.

In the present invention, it is technical to use one or two or more of a cyclopentanone solution, a cycloheptanone solution, a cyclohexanone solution, or a cyclohexanol solution having a functional group of a ketone in the blocker. It is characteristic. Preferably, the use of a cyclonuxanone solution has the effect of significantly removing the influence of the interference factor.

 The cyclopentanone solution, cycloheptanone solution, cyclohexanone solution, or cyclohexanol solution of the present invention may contain cyclopentanone, cycloheptanone, cyclonuxanone, or cyclohexanol in an organic solvent or water (required In some cases, it means dissolved by using a surfactant).

In particular, the cyclohexanone solution of the present invention (Cyclohexanone Solution) means that dissolved in the organic solvent or water cyclone nucleonone. Therefore, of course, it can also melt | dissolve using a surfactant as needed.

Cyclonucleanone, also known as pimerine ketone or ketocyclohexane, is a cyclic molecule consisting of six carbon atoms containing a functional group of a ketone, is an aliphatic cyclic ketone, and is generally used as an activator in an oxidation reaction.

In the present invention, the cyclonuxanone solution acts to increase the detection sensitivity of zinc ions in detecting zinc ions and to significantly block the interference of other interference ions.

In the present invention, a cyclohexanone solution, which is the above-mentioned interfering factor blocking agent, is added to a zinc-containing sample, and the zinc reagent of the present invention is added to mix and react with the sample and develop color. The time for the mixing reaction may be about 20 seconds to 3 minutes, preferably about 1 minute.

During the reaction time, the cyclohexanone solution (Cyclohexanone Solution) and the zinc reagent (Zinc reagent) and the zinc (Zn, Zinc) encounters through the interaction to form a colored compound bond.

In the present invention, zinc or zinc is compared with or compared with the degree of color development produced by mixing the color reaction and the color reaction by the above-described interference ion blocking agent and zinc reagent with respect to the standard solution for each zinc ion concentration. Provided are methods for measuring the concentration of ions.

The method of contrasting or comparing the degree of color development between the sample and the standard solution may be employed in various ways. Preferably, the concentration of zinc (Zn, Zinc) or zinc ion may be calculated by using an absorbance method or colorimetric control. have.

Therefore, the present invention can calculate the concentration of zinc ions in a sample by using an absorbance or colorimetric control to mix the above-described zinc reagent and cyclonuxanone solution into the sample and develop the color thereof.

Referring to the zinc ion concentration detection method using the zinc reagent and the interference ion blocker of the present invention as follows.

The present invention performs a process of generating a sample by reacting a sample by mixing a interference ion blocker (cyclonuxanon solution) and a zinc reagent to the sample.

A control solution is prepared for a standard solution of various concentrations of zinc ions, and a calibration curve or reference value is prepared, and the absorbance of the sample solution is measured, and the zinc ion concentration is detected by comparing with the calibration curve or reference value.

Alternatively, a method such as a color contrast table for detecting zinc ion concentration by comparing the reference value of the control solution with respect to the standard solutions of various concentrations and the degree of color development of the sample solution is performed.

It provides a method for detecting the zinc ion concentration through the above process.

The absorbance method used in the present invention means a conventional method of determining the concentration of the target component by measuring the degree of light absorption at a specific wavelength by changing the target component in the sample solution into a light absorbing material with a suitable reagent.

The absorbance method of the present invention obtains the concentration of a target component by applying Lambert Beer's law. A typical absorbance analyzer includes a light source unit, a wavelength selection unit, a sample unit, and a photometric unit.

As a method of measuring the concentration in the absorbance method, there is a colorimetric method using the degree of color development, and a turbidity method using the degree of suspension of the sample solution. Absorption spectroscopy makes a control solution corresponding to the sample liquid to measure the absorbance, and accordingly prepares a calibration curve and then measures the absorbance of the sample liquid and compares the concentration with the calibration curve.

In the present invention, both the colorimetric method and the colorimetric method can be used, and preferably, the colorimetric method has high accuracy.

In addition, the colorimetric contrast method is as follows.

As described above, a standard solution is prepared according to various concentrations of a desired component, and the reference colorimetric table is established by combining the cyclonuclisonone solution and the zinc reagent with respect to the standard solution.

And it means the method of measuring the density | concentration of a sample liquid by comparing the color development degree which mixed and mixed said cyclonuxanone solution and zinc reagent with the sample with the said reference colorimetric table.

Therefore, the present invention will include any method for measuring the concentration of zinc ions using the degree of miscibility of the zinc reagent of the present invention to a sample and its color development.

For this reason, the present invention provides a zinc ion detection kit for use in the absorbance measurement method or the colorimetric contrast measurement method, which is the method for measuring zinc.

Hereinafter will be described an embodiment according to the present invention. However, the embodiment of the present invention does not limit the technical content of the present invention or reduce the scope of rights.

<Examples>

1. Zinc Reagent Preparation

Reagent 1

Potassium Borate 50g

CAS No .: 1332-77-0

Reagent 2

Zincon monosodium salt 0.1 g

CAS No .: 135-52-4

Reagent 3

20 g Boron Oxide

CAS No .: 1303-86-2

Reagent 4

Sodium Ascorbate 20g

CAS No .: 134-03-2

[Reagent 5]

Potassium Cyanide 10.9g

CAS No .: 151-50-8

Was mixed in the above weight to prepare a zinc reagent in powder form.

2. Manufacture of blocker blockers

Reagent 1

Cyclohexanone

CAS No .: 108-94-1

100 ml of the above solution is prepared.

3. Zinc ion concentration detection kit

(1) Provides a water quality analysis kit capable of measuring the zinc ion concentration including the zinc reagent described above and including reagents for other water quality analysis items.

(2) Provides a water quality analysis kit capable of water quality analysis, including the above-described zinc reagent and blocker blocker and including reagents for other water quality analysis items.

(3) The present invention also provides a zinc ion concentration detection kit including the zinc reagent and the blocker of blocking agent, and comprising an absorbance spectrometer or colorimetric control unit capable of measuring water quality, including reagents for other water quality analysis items.

4. Zinc ion concentration detection method

Take 10 ml of sample containing zinc ions.

1 ml of Cyclohexanone Solution is mixed and mixed with the sample.

Then, 1 mg of zinc reagent powder is taken, mixed with the sample, reacted, and developed. The reaction time lasted about 1 minute.

The concentration of zinc ions was measured using an absorbance spectrometer on the colored samples.

The measurement wavelength used at the time of absorbance was 620 nm, and the measuring vessel diameter 5 inch round glass bottle was used.

The control calibration curve for the standard solution is shown in FIG. 1.

Alternatively, a colorimetric table is prepared for the standard solution, and the concentration of zinc ions is calculated by comparing the degree of color development with respect to the color-induced sample.

As shown in Table 1 below, the present invention exhibits a high limit that can exclude the effects of ion interference.

Therefore, when using the detection kit for measuring the zinc ion concentration according to the present invention it can be seen that the effect of significantly reducing the effect of interference by other kinds of ions contained in the sample.

Interference Limit value (mg / l) Aluminum 10 mg / l Cadmium 50 mg / l Copper 50 mg / l Iron 50 mg / l Manganese 50 mg / l Nickel 100 mg / l

Zinc ion concentration detection method and detection kit according to the present invention can be widely used in water purification and sewage treatment business, pollution prevention industry, education business related to the basic framework of the water environment.

In addition, the present invention can be widely used for pollution prevention monitoring industry, environmental policy related business of national and local government.

In addition, it is a very useful invention for water quality analysis chemicals business, water quality analysis chemical manufacturing industry, environmental supervision business, environmental modeling business, environmental impact assessment business and educational data providing business.

Claims (5)

In the reagent used for detecting zinc ion concentration,
Borate, Zincon monosodium salt (2-carboxy-2 '-hydroxy-5' sulfoformyl-benzene sodium salt), boron oxide, ascorbate, Zinc reagent mixed with cyanide.
The method of claim 1,
Borate is potassium metaborate KBO ₂ , metaborate such as sodium metaborate NaBO ₂ , tetraborate such as borax Na ₂ B ₄ O ₇ · 10H ₂ O, pentaborate such as KB ₅ O ₈ · 4H ₂ O, peroxide or Using one or two or more hypoborate salts,
Boron oxide is used by using one or two or more of boron dioxide, diboron trioxide, tetraboron trioxide or tetraboron pentoxide,
Ascorbate uses sodium ascorbate,
A cyanide is a zinc reagent, characterized by using potassium cyanide.
Containing the zinc reagent of any one of claims 1 and 2,
A zinc ion concentration detection kit comprising a cyclopentanone solution, a cycloheptanone solution, a cyclonuxanone solution, or a cyclohexanol solution, comprising a blocker for blocking one or two or more thereof.
A process of coloring a sample by mixing a blocking agent and a zinc reagent with one or more of cyclopentanone solution, cycloheptanone solution, cyclonuxanone solution, or cyclohexanol solution,
A method of measuring zinc ion concentration by comparing the color development degree of the sample with the color development with that of the standard solution.
5. The method of claim 4,
As a method of comparing and contrasting the degree of color development, a method of measuring zinc ion concentration, characterized by using the absorbance method or colorimetric contrast method.

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