KR100336979B1 - Method for measuring resistivity of fused glass - Google Patents

Abstract

PURPOSE: A method for measuring resistivity of a fused glass is provided to reduce the measuring error by measuring an electric resistance using a liquid whose resistivity is known at room temperature. CONSTITUTION: An electric resistance measuring cell is comprised of an alumina furnace(10) filled with a fused glass(1) and two electrodes(12), each of which has a diameter of 1 mm and is made of an alloy of Pt 70% and Rh 30%. The electrodes(12) have a space of 18 mm therebetween. A temperature of the fused glass(1) is measured by a thermocouple(14) installed together with the electrodes(12) and a temperature indicator(30) connected to the thermocouple(14). The electrodes(12) and the thermocouple(14) are protected by an alumina protecting tube(11). A compensation of the electric resistance measuring cell is performed at a low frequency domain by using the fused glass(1) whose resistivity is known at 1000-1300°C.

Description

Resistivity Measurement Method of Molten Glass

The present invention relates to a method for measuring the resistivity of molten glass, and more particularly, a two-component alkali silicate in which the resistivity measuring cell of the molten glass is already known in a very low frequency region at a high temperature of 1000 ° C. or more, rather than a low temperature. By directly correcting using molten glass, the present invention relates to a new resistivity measuring method which is easy to measure and reproducible while reducing errors.

Glass raw materials are mainly melted in the furnace by the combustion of liquid or gaseous fuels, but additional electric boosters (generally metal electrodes) are installed to prolong the lifetime of the furnace, improve the productivity of the glass and reduce emissions. The melting method is widely used. Therefore, when installing a booster in the furnace, it is essential to know the electrical resistivity of each temperature for the glass to be melted in order to accurately determine the number, size, arrangement, and power of electrodes suitable for the furnace. However, unlike the measurement of the resistivity of solid state at room temperature, the measurement of resistivity of molten glass at high temperature is very difficult. Several methods developed to date with regard to the measurement of electrical resistance of molten glass can be roughly classified into compensation and absolute methods.

Here, the compensation method is a method of calibrating a measuring cell at room temperature using various concentrations of potassium chloride or sodium chloride salt solution having known resistivity [Reference: 1. Physics and Chemistry of Glasses. 8 (1967), pp. 101-112, United Kingdom, 2. Glastechnish Berichte, 56K (1983), pp. 509-514, Germany].

And, the absolute method is a method of directly measuring the resistance of the glass depending on the size of the cell at a high temperature without correction of the measuring cell [Reference; 1. Journal of Ceramic Society Japan, 91 (1993), pp. 334-338, Japan, 2. Glastechnische Berichte, 49 (1976) pp. 157-161 and 62 (1989) pp. 122-126, Germany].

However, the above two methods have some problems in measurement.

Although the actual glass shows, for example, Na ₂ O / SiO ₂ (20/80 molar ratio) glass, as shown in 2-2 of FIG. The resistance of the salt solution for the correction of potassium chloride or sodium chloride used in the present invention is very dependent on the frequency as shown in 2-1 of FIG. 2 of the accompanying drawings, so that in order to obtain a low polarization resistance, that is, In order to obtain the resistance, a high frequency range of 1 to 100 kHz is required at the time of correction.

In addition, since the correction is made at room temperature, the correction constant must be recalibrated at high temperature in consideration of thermal expansion of the cell and glass.

In the case of the absolute method, the reliability of the measurement result is good, but the structure of the cell is very complicated and it is impractical because the measurement takes a long time of 10 to 30 hours.

Therefore, the present invention improves the disadvantages of the compensation method of the conventional method, that is, the contradiction of correcting the correction coefficient obtained by using various concentrations of salt solutions at room temperature again at high temperature, and using a two-component alkali silicate molten glass directly at high temperature. The purpose of this method is to provide a resistivity measurement method that is easy to measure, reproducible, and practically applicable to the glass industry.

Hereinafter, the present invention will be described in detail.

The present invention provides a method of correcting a specific resistance measurement cell by measuring an electrical resistance using a liquid having a specific resistance value at room temperature to obtain a correction coefficient, and then applying the measurement to the specific resistance value of the molten glass. The calibration of the measuring cell is characterized in that it is carried out in a very low frequency region by using a binary alkali silicate molten glass having a specific resistance value at 1000 to 1300 ° C.

Referring to the present invention in more detail as follows.

The present invention relates to a specific resistance measuring method which can be easily applied to the glass industry by making electrical resistance measurement of glass melting easy. The configuration of the resistance measuring cell of the present invention is an electrode in glass as shown in FIG. It is similar to the conventional compensation method of penetrating the.

The resistance cell in a vertical furnace consists of an alumina crucible 10 filled with molten glass 1, two electrodes 12 mm in diameter composed of 70% Pt and 30% Rh alloy penetrated into the molten glass. . The two electrodes 12 are spaced at an interval of 18 mm, and the temperature of the molten glass is measured by a thermocouple 14 installed with the electrodes and a temperature indicator 30 connected thereto. The two electrodes and the thermocouple are wrapped in an alumina protective tube 11 to be protected.

The resistance measuring instrument uses an impedance bridge (LCR meter) 20 having a frequency of 1 kHz or more, and the electrode is lowered into the furnace at a constant speed by a motor installed at the upper part of the furnace, and when contacted with the molten glass 1, the impedance bridge ( It stops automatically by reaction of 20).

By this method, the electrical resistance of the glass can be measured at a viscosity of up to approximately 10 ^4.5 dPa · s, but commercial glass may be measured at about 1000 ° C. or more, depending on the composition.

As described above, when the resistance value of the molten glass is to be measured, first, the electrical resistance measurement cell should be corrected.

Regarding the resistance of an object, the specific resistance of an object is proportional to the resistance of the object as shown in the following equation (I).

ρ = R / (L / A), L / A = K (I)

In the above formula,

ρ is the specific electrical resistivity of the object (Ωcm),

R is the resistance of the object (Ω), and L (cm) and A (cm 2) are either solid materials or directly determined by length and cross-sectional area in the absolute method, but in the case of liquid, as in the compensation method, the shape is not constant. K (/ cm: correction constant) depends on the structure of the cell, in particular the diameter of the electrode and the depth of penetration in the liquid.

Therefore, in order to actually calculate the correction constant K, the resistance is measured using a liquid which already knows the specific resistance in a state where the penetration depth of the electrode in the liquid is constant, and then it is determined by the above formula (I). In the compensation method, as described above, the correction of the cell is generally performed using a KCl solution at room temperature, and as shown in 2-1 of FIG. Measure the resistance up to the high frequency range Extrapolate by the formula (f: frequency, F: inverse of frequency).

However, the present invention is a method of directly correcting a cell using a glass having no frequency dependency as shown in 2-2 of FIG. 2 in the accompanying drawings at a high temperature of 1000 to 1300 ° C. _Two- component alkali silicate molten glass is used, which is Na ₂ O / SiO ₂ (20/80 molar ratio), or K ₂ O / SiO ₂ (20/80 molar ratio), which shows very good agreement. These glasses have known resistivity values with respective temperatures within the range of 1000 to 1300 ° C. The resistance measurement time is 4 to 5 hours, and the resistance value is measured at a depth of 10 mm in which the electrode is penetrated into the alumina crucible filled with the bicomponent alkali silicate molten glass in a cell having a configuration as shown in FIG. . At this time, the frequency is in the range of 1 ~ 10 kHz where the polarization of the electrode can be ignored.

If you draw a graph about the known specific resistance value according to the measured resistance value for each temperature, it becomes a straight line, and the inverse of the slope (1 / K) of the straight line becomes the correction constant (K) to be obtained.

Once the correction constant is obtained, the electrode is immersed in HF solution for about a day and then the remaining glass attached to the electrode is removed with a soft brush and water. And when arbitrary molten glass is put into an alumina crucible and a resistance value is measured by the same method, specific resistance value ( rho) (ohm * cm) is calculated | required by said formula (I) using the correction constant calculated | required previously.

The measurable viscosity of any glass is up to about 10 ^4.5 dPa · s. Glass having a viscosity exceeding this value is difficult to penetrate the electrode and cannot measure the resistance value.

In this way, the present invention which corrects the electric resistance measurement cell with molten glass directly at high temperature is applied only the correction coefficient determined at the same frequency at all times, if only the correction coefficient by molten glass is determined at high temperature at a fixed frequency of 1 to 10 kHz. Since it is possible to investigate the electrical resistance of molten glass in a short time without expensive high frequency measuring instrument, it can be practically adopted in glass industry.

Hereinafter, the present invention will be described in detail with reference to the following Examples, but the present invention is not limited by the Examples.

Reference example: Determination of the correction constant (K)

As shown in FIG. 1, the alumina crucible was filled with Na ₂ O / SiO ₂ (20/80 molar ratio) molten glass, and the electrode was penetrated to a depth of 10 mm, and the frequency was fixed at 4 kHz. Here, the specific resistance value according to 1000 ℃, 1100 ℃, 1200 ℃, 1300 ℃ of the molten glass is as shown in Table 1 below.

Then, the electrical resistance value R at each temperature was measured by an LCR meter, and the known resistivity value ρ was plotted as shown in FIG.

From the results in FIG. 3, a straight line was obtained as expected in Equation (I), and the correction constant K was obtained from the inclination thereof, and was 1.06 / cm.

Also, a result of using the two-component alkali silicate molten glass in K ₂ O / SiO ₂ (20/80 molar ratio) obtained by a specific resistance value by the above method is also the same.

Example 1

In order to investigate the reliability of the reference example, the electrical resistance was measured by the above-described method on commercial alkali borosilicate glass (Schott Glass, Germany) of three compositions in which the specific resistance was known by absolute method measurement. Specific resistance (Ωcm) was calculated using K = 1.06 / cm).

Then, the resistivity values of the three glasses with temperature were plotted and the results are as shown in FIG.

Example 2

For three barium silicate glasses (TV CRT, Samsung Corning Co., Ltd.), the electrical resistance was measured by the method of the above reference example, and the specific resistance (Ωcm) was calculated using the obtained correction constant (K = 1.06 / cm). It was.

Then, the resistivity values of the three glasses with temperature were plotted, and the results are as shown in FIG.

The graph of the temperature dependence of the specific resistance values from the results of Examples 1 and 2 shows linearity. In general, the specific resistance (log ρ ) with respect to the inverse of the temperature (1 / T) in the narrow high temperature region is as follows. It satisfies the same Rasch-Hinrichsen equation and shows linearity.

log ρ = A + B / T

In the above formula,

A and B are constants,

T is the absolute temperature

Slope B contains the activation energy for ion conduction.

Therefore, the results of the calculation of the correction constant by the correction of the electrical resistance measurement of the present invention show that the result of the absolute method shown in the solid line in the very small error range.

1 is a cross-sectional view showing a measuring cell of the molten glass resistivity measuring apparatus used in the present invention,

2 is a graph showing the electrical resistance value according to the frequency change of the solution used in the correction of the electrical resistance cell by the compensation method,

2-1: When using a salt solution at room temperature as a conventional method,

2-2: In case of using Na ₂ O / SiO ₂ (20/80 molar ratio) glass at high temperature (1315 ° C) as the present invention

3 is a graph showing the specific resistance value according to the resistance value as a result of the correction of the electrical resistance cell using the two-component alkali silicate molten glass according to the reference example of the present invention,

4 is a graph showing the temperature dependence of the specific resistance value of the commercial borosilicate molten glass of three compositions according to the measurement result of Example 1 of the present invention,

5 is a graph showing the temperature dependence of the specific resistance value of the barium silicate molten glass of three compositions according to the measurement result of Example 2 of the present invention.

[Description of Code for Major Parts of Drawing]

1-molten glass, 10-alumina crucible,

11-alumina protective tube, 12-electrode [Pt / Rh = 70/30],

14-thermocouple, 20-impedance bridge (LCR meter),

30-temperature indicator.

Claims (3)

In the method of applying the electric resistance measurement cell in a method of measuring the electrical resistance by measuring the electrical resistance using a liquid having a known specific resistance value at room temperature to obtain a correction coefficient, and then applying it to the measurement of the specific resistance of the molten glass. Correction is carried out in a very low frequency region using a two-component alkali silicate molten glass having a specific resistance value at 1000 ~ 1300 ℃, characterized in that the resistance measurement of the molten glass. _2. The resistivity of the molten glass according to claim 1, wherein the two-component alkali silicate molten glass comprises Na ₂ O and SiO ₂ in a 20:80 molar ratio or K ₂ O and SiO ₂ in a 20:80 molar ratio. How to measure. The method of measuring resistivity of molten glass according to claim 1, wherein the frequency range used during the correction is 1 to 10 kHz.