KR20230072066A - a correction method for disolved oxygen sensors - Google Patents

Abstract

The present invention relates to a dissolved oxygen scavenger used when measuring dissolved oxygen in water and a method for correcting a dissolved oxygen sensor.
In the present invention, after immersing the dissolved oxygen sensor in the dissolved oxygen scavenger, the process of reading the output signal through the dissolved oxygen meter while stirring the liquid (step 1),
The process of setting the reference time by measuring the time until the signal output from the dissolved oxygen meter reaches a specific value (zero value) (step 2),
The process of washing the dissolved oxygen scavenger by washing the sensor of the dissolved oxygen meter with distilled water (step 3);
A method for calibrating a dissolved oxygen sensor is provided.
In addition, the present invention measures the signal value and time that do not change any more if the signal value is not output as a specific value (zero value) in the above two steps, and sets the signal value and time as the reference value and reference time (2) It provides a method for calibrating a dissolved oxygen sensor, further comprising Step-2).
In addition, the present invention provides a method for calibrating a dissolved oxygen sensor, wherein the dissolved oxygen scavenger is prepared by mixing demineralized water, sodium sulfite, and cobalt chloride hexahydrate. .

Description

Calibration method of dissolved oxygen sensors {a correction method for dissolved oxygen sensors}

The present invention relates to a dissolved oxygen scavenger used when measuring dissolved oxygen in water and a method for correcting a dissolved oxygen sensor.

Methods for measuring the amount of dissolved oxygen can be largely divided into optical methods and electrochemical methods.

As for the optical method, methods of measuring quenching of a material emitting fluorescence or phosphorescence by oxygen or measuring a change in absorption by a reversible bond with oxygen using a spectrometer are generally used.

This optical method generates a very stable signal because it is based on the equilibrium reaction between an appropriate indicator substance and oxygen, but requires a sample pretreatment step because it is affected by the turbidity of the sample, and components such as a light source and a spectrometer are required. Because of the high price, analysis equipment is expensive, and the analysis device is complicated, so there are disadvantages in that it is difficult to miniaturize for on-site measurement.

The dissolved oxygen sensor using the electrochemical method includes a sensor using a Clark type amperometry, a galvanic sensor, and a solid-state electrolyte potentiometric method capable of measuring gaseous oxygen at high temperature. potentiometry) sensors, etc., and among these sensors, the sensor using the Crack type current method and the galvanic sensor are economical and easy to handle, so they are most widely used.

In particular, in the sensor using the Crack-type current method, when dissolved oxygen diffuses to the surface of an electrode through a gas permeable membrane, it is reduced by a reduction potential applied to the surface of the electrode, and the amount of dissolved oxygen is quantified by measuring the reduction current generated at this time. can do.

In the sensor using the Crack-type current method, since the sensitivity characteristics depend on the characteristics of the gas permeable membrane, arrangement, sealing, and structure related to the gas permeable membrane are important factors.

Samples other than dissolved oxygen should not permeate into the electrode through the permeable membrane, and the electrolyte should be able to reach the anode and cathode easily.

That is, whether or not the amount of dissolved oxygen can be accurately measured is determined according to the arrangement relationship between the electrode and the transmission membrane and the degree of sealing of the transmission membrane.

Regarding this technology, Registration Patent No. 10-2280031 (Dissolved Oxygen Measurement Sensor Performance Evaluation Apparatus) describes "a first tank containing a zero solution; a second tank containing a 20°C saturated dissolved oxygen solution; and a 30°C saturated dissolved oxygen solution. A third water tank containing three dissolved oxygen measuring sensors; Three jigs capable of alternately immersing the three dissolved oxygen measuring sensors in the first to third water tanks while holding each of the three dissolved oxygen measuring sensors; The three dissolved oxygen measuring sensors Dissolved oxygen measuring sensor performance evaluation apparatus, characterized in that it includes cables connected to each of the cables to transmit the sensed values of the dissolved oxygen measuring sensors, and a recording device connected to the cables and recording the sensed values transmitted from the cables. " has been provided.

In the case of the above prior art and prior art, the dissolved oxygen sensor calibration is performed by adding chemicals to pure water to make a zero concentration solution, blowing air to saturate oxygen to make a saturated solution, and then correcting using two solutions. ,

As a zero-concentration solution, anhydrous sodium sulfite dissolved in distilled water is used, but it is inconvenient to use, and a zero-concentration solution in which anhydrous sodium sulfite is dissolved in distilled water is not a completely zero solution, so some errors occur, and such a zero-concentration solution There was a problem that it took a lot of time to calibrate the zero point of the contained sensor.

An object of the present invention is to solve the above problems and to provide a method for calibrating a dissolved oxygen sensor using a dissolved oxygen scavenger that is remarkably convenient in use and does not take much time to perform zero point calibration.

In order to solve the above problems and needs, the present invention

The process of immersing the dissolved oxygen sensor in the dissolved oxygen scavenger and reading the output signal through the dissolved oxygen meter while stirring the liquid (step 1);

The process of setting the reference time by measuring the time until the signal output from the dissolved oxygen meter reaches a specific value (zero value) (step 2),

The process of washing the dissolved oxygen scavenger by washing the sensor of the dissolved oxygen meter with distilled water (step 3);

A method for calibrating a dissolved oxygen sensor is provided.

In addition, the present invention measures the signal value and time that do not change any more if the signal value is not output as a specific value (zero value) in the above two steps, and sets the signal value and time as the reference value and reference time (2) It provides a method for calibrating a dissolved oxygen sensor, further comprising Step-2).

In addition, the present invention provides a method for calibrating a dissolved oxygen sensor, wherein the dissolved oxygen scavenger is prepared by mixing demineralized water, sodium sulfite, and cobalt chloride hexahydrate. .

In the method for calibrating a dissolved oxygen sensor according to the present invention, as a dissolved oxygen scavenger from which dissolved oxygen is completely removed is used, no calibration error of the dissolved oxygen sensor occurs and the time required is remarkably shortened, resulting in remarkably high user convenience.

1 is a flow chart of a method for calibrating a dissolved oxygen sensor according to the present invention.

Hereinafter, the present invention will be described in detail.

The present invention provides a method for correcting a dissolved oxygen sensor used when measuring dissolved oxygen in water.

In general, the dissolved oxygen sensor calibration method is performed as follows.

1. Dissolved Oxygen Sensor Calibration Method

In general, dissolved oxygen sensor calibration is performed by adding chemicals to pure water to make a zero concentration solution, blowing air to saturate oxygen to make a saturated solution, and then using two solutions to calibrate.

However, in the case of a site (sewage treatment plant, lake treatment plant, etc.), since such a correction method is difficult for a user to execute, a correction method using oxygen concentration in the atmosphere is mainly used.

In the case of the air calibration method, salinity compensation is not required, but humidity compensation is necessary.

If humidity is not calibrated, a relative error of ±2.5% is given.

In addition, barometric and hydrostatic corrections for altitude (300m, 30mmHg, 5% relative error) and water surface (0.4m, 30mmHg, 5% relative error) are required.

2. Correction factor of dissolved oxygen sensor before shipment

A. Thermometer calibration: Since temperature compensation is based on accurate temperature measurement, use a standard thermometer to calibrate to 0.1 °C.

B. Zero correction: Check the offset of the electronic circuit with a chemical zero solution, and check how much the zero signal of the electrode is.

C. Membrane temperature compensation: As the most important compensation, it quantifies how the oxygen permeability of the membrane changes according to the temperature.

D. Compensation for air/water sensitivity: Measure the oxygen sensitivity in the air during air calibration to estimate the oxygen dissolved in water, so the signal ratio is measured for each temperature within the drawing temperature range.

3. Dissolved Oxygen Sensor Performance Evaluation Method

Electrode-type dissolved oxygen monitors can have different sensitivities depending on the geometry of the electrodes during the manufacturing process, so calibration is essential.

Dissolved oxygen sensors have different output characteristics. If the membrane in the sensor is exchanged or the sensor has been used for a long time or has not been used, recalibration is required.

The present invention is a method for calibrating using two solutions after adding chemicals to pure water used in the above-mentioned dissolved oxygen sensor calibration to make a zero concentration solution, blowing air to saturate oxygen to make a saturated solution, It is an invention about

In the present invention, after immersing the dissolved oxygen sensor in the dissolved oxygen scavenger, the process of reading the output signal through the dissolved oxygen meter while stirring the liquid is performed. (Step 1)

The dissolved oxygen sensor used in the present invention refers to a sensor using a Clark type amperometry, a galvanic sensor, and the like.

The dissolved oxygen meter of the present invention refers to a device or tool capable of measuring dissolved oxygen by including the above-described dissolved oxygen sensor.

A technical feature of the present invention lies in the above dissolved oxygen scavenger, and is that the zero point (zero value) correction of the sensor can be easily and simply performed using the dissolved oxygen scavenger.

The dissolved oxygen scavenger of the present invention means a composition obtained by mixing demineralized water, sodium sulfite, and cobalt chloride hexahydrate.

The present invention preferably means a dissolved oxygen scavenger prepared by mixing 2 to 9 parts by weight of sodium sulfite and 0.1 to 3 parts by weight of cobalt chloride hexahydrate in 100 parts by weight of demineralized water. do.

The above-described distilled water (Demineralized water) of the present invention means pure water without foreign substances, that is, water distilled by a still.

Sodium sulfite of the present invention is also referred to as sodium sulfite as sodium sulfite. Formula Na2SO3. It is usually obtained as heptahydrate Na2SO3·7H2O. Colorless crystals, specific gravity 1.59. Above 37°C, it becomes anhydrous. Anhydrous salt is colorless crystals or powder and is decomposed by heating. It oxidizes slowly in air, but is more stable than heptahydrate.

It is obtained by passing sulfur dioxide (sulfurous acid gas) through an aqueous solution of sodium carbonate to make a sodium hydrogen sulfite solution, neutralizing it with an equivalent amount of sodium carbonate, and evaporating and concentrating at 37 ° C or lower. It also occurs when a thick solution of sodium hydroxide is cooled and neutralized by passing sulfur dioxide therethrough.

Cobalt chloride hexahydrate of the present invention is cobalt chloride hexahydrate, and cobalt is a transition metal mainly having a +2-valent or +3-valent oxidation state, and representative salts thereof are cobalt chloride CoCl2 and CoCl3.

Of these, CoCl2 is the more stable and widespread salt. Cobalt(II) chloride anhydride (CoCl2) is a light blue solid. Cobalt(II) chloride anhydride can readily hydrate to form various types of hydrates. Depending on the number of water molecules included, hydrates such as CoCl2·H2O, CoCl2·2H2O, and CoCl2·6H2O exist, but neither 3H2O nor 4H2O has been identified. Of these, CoCl2 2H2O is purple, and CoCl2 6H2O is dark pink to purple. CoCl2 6H2O is the most commonly encountered state of cobalt chloride.

In the present invention, a dissolved oxygen scavenger was prepared in the following examples.

<Example>

1. Preparation of dissolved oxygen scavenger

Reagent 1.

Synonyms: Demineralized water

CAS No.: 7732-18-5

reagent 2.

Synonyms: sodium sulfite

CAS No.: 7757-83-5

reagent 3.

Synonyms: Cobalt chloride Hexahydrate

CAS No.: 7791-13-1

The combination composition ratio of the dissolved oxygen scavenger is shown in [Table 1].

Reagent # reagent 1 reagent 2 reagent 3 Weight ratio (%) 95 4 One

In the present invention, the process of setting the reference time by measuring the time until the signal output from the dissolved oxygen meter reaches a specific value (zero value) is performed. (Step 2)

That is, in the present invention, after waiting until the signal output from the dissolved oxygen meter becomes a specific value (zero value) after the above process, the signal value and time when the dissolved oxygen sensor was first immersed are recorded, and the signal is The time when a specific value (zero value) is recorded is recorded, and the reference time is set by performing a process of measuring how long the specific value (zero value) is reached.

This reference time of the present invention usually takes about 1 to 2 minutes, and when the same dissolved oxygen meter is corrected later (zero value correction), the dissolved oxygen sensor is immersed in the dissolved oxygen scavenger for the reference time to be calibrated.

In the present invention, if the signal value is not output as a specific value (zero value) in the above process (process 2), the process of measuring the signal value and time that does not change anymore and setting the signal value and time as the reference value and reference time (Process 2-2)

When the signal output from the dissolved oxygen meter does not become a specific value (zero value), a process of setting the signal value that has not changed any more as a reference value and setting the time as the reference time is performed.

The above-described reference value and reference time function to compensate by immersing the dissolved oxygen sensor in the dissolved oxygen scavenger during the reference time when correcting the same dissolved oxygen meter (zero value correction), and subtracting and correcting by the reference value.

In the present invention, after the above process, the sensor of the dissolved oxygen meter is washed with distilled water to clean the dissolved oxygen scavenger. (Step 3)

If the dissolved oxygen scavenger attached to the sensor of the dissolved oxygen meter is not sufficiently cleaned in the above 2 steps, the remaining dissolved oxygen scavenger is mixed into the oxygen bleaching solution and consumes dissolved oxygen to lower the dissolved oxygen concentration. process is needed.

In the present invention, up to the above three processes refer to a process of zero point correction of the dissolved oxygen sensor.

In the present invention, after the above process, the sensor of the dissolved oxygen meter is immersed in an oxygen saturated solution to correct the dissolved oxygen saturation value. (Step 4)

In the present invention, the dissolved oxygen measurement and correction of the dissolved oxygen sensor is performed through the process of correcting the zero point of the dissolved oxygen sensor and correcting with the dissolved oxygen saturation value as described above.

The present invention provides a method for calibrating a dissolved oxygen sensor having the above configuration and functions.

The present invention is useful for industries producing, manufacturing, selling, distributing, and researching devices for measuring dissolved oxygen.

In particular, the present invention is useful for industries that produce, manufacture, sell, distribute, and research reagents used to calibrate dissolved oxygen meters.

Claims (3)

The process of immersing the dissolved oxygen sensor in the dissolved oxygen scavenger and reading the output signal through the dissolved oxygen meter while stirring the liquid (step 1);
The process of setting the reference time by measuring the time until the signal output from the dissolved oxygen meter reaches a specific value (zero value) (step 2),
The process of washing the dissolved oxygen scavenger by washing the sensor of the dissolved oxygen meter with distilled water (step 3);
Calibration method of dissolved oxygen sensor including.
According to claim 1,
If the signal value is not output as a specific value (zero value) in step 2 above, the process of measuring the signal value and time that does not change anymore and setting the signal value and time as the reference value and reference time (Step 2-2) A method for calibrating a dissolved oxygen sensor, further comprising:
According to claim 1 or 2,
The dissolved oxygen scavenger is a method for calibrating a dissolved oxygen sensor, characterized in that it is formed by mixing demineralized water, sodium sulfite, and cobalt chloride hexahydrate.

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