KR200462384Y1 - Test kit for measuring total acid value of transformer oil - Google Patents

Abstract

The present invention is a transparent material having a housing that forms an inner space of which one end is opened, and a container in which a mixed liquid containing a mixed solvent and an indicator is mixed in the inner space of the housing, and the open end is sealed by a stopper; Provided is a device for measuring the computer value of an electric insulating oil, which is provided for mixing with a mixed solution and which contains a titration liquid contained in the container and another container.

Description

TEST KIT FOR MEASURING TOTAL ACID VALUE OF TRANSFORMER OIL

The present invention relates to a mechanism for measuring the total value of electrical insulating oil for measuring the total value of the electrical insulating oil injected into the power equipment.

Electrical insulating oil is oil used for electrical insulation and cooling of power equipment (equipment) such as transformers, capacitors, cables, and circuit breakers.

In the transformer, a diaphragm capacitor method or a nitrogen encapsulation method is used so that insulating oil and air do not contact each other. However, due to factors such as long-term use of the transformer or effects of heat, oxidizing substances are generated in the insulating oil. This causes the function of electrical insulation of the electrical insulating oil to be degraded. This is called deterioration.

As electrical insulating oils deteriorate, they are affected by appearance (color), dielectric breakdown voltage, computer value, volume resistivity, etc., which leads to a decrease in the performance of electrical insulating oils. Inadequate power supply can lead to transformer accidents.

Therefore, the degree of deterioration of the electrical insulating oil is evaluated by grasping the above characteristics of the electrical insulating oil through the electrical insulating oil. Among the above characteristics of electric insulating oil in a transformer in operation, computer value measurement is an important factor in deterioration judgment. This is because it is possible to determine whether to replace the insulating oil and further prevent the transformer accident. The total value is the number of mg of potassium hydroxide required to neutralize all the total acid contained in 1 g of electrically insulating oil.

1 is a conceptual diagram showing a conventional computerized measuring instrument.

As shown in FIG. 1, a conventional computerized measuring instrument is composed of a container 10, a support 20, and glass ampoules 30 and 40. FIG.

The container 10 has an interior space for receiving the support 20 and the glass ampoules 30 and 40. The inner space is open through one end of the container 10, which can be closed by a stopper 5. Reagents (mixed solvents) for measuring the acid value may be further accommodated in the inner space of the container 10.

The support 20 has a structure capable of fixing the glass ampules 30 and 40. Into the glass ampoules 30 and 40, the indicator and the titrant are respectively filled and sealed in an appropriate manner. The indicator and the titrant are separated from each other and stored in the container 10 without being mixed with each other.

In the field, when the acid value is measured, the outer surface of the container 10 is strongly pressed by hand to break the glass ampoules 30 and 40 so that the reagents in the container 10 are mixed with each other. This makes it possible to prevent the deterioration of the reagents as compared to the case where the reagents are kept mixed before use. The computational value is measured by adding electrical insulating oil to the mixed reagents and observing the color change. Electrical insulating oil is injected into a disposable pipette.

At this time, the container 10 is made of polyethylene (polyethylene) material having excellent flexibility in order to destroy the ampoules (30 and 40). However, in the case of the measurement method using the colorimetric method, in which the color of the mixed liquid (mixed solvent + reagent + electrical insulating oil) changes according to the degree of deterioration of the electrical insulating oil, since the polyethylene itself is translucent, the color of the mixed liquid cannot be clearly determined, causing the error. It can also be. In particular, when the electric insulating oil is used for a long time, it is often changed to yellowish brown itself. Therefore, it is difficult to distinguish whether the yellowish brown is the color of the insulating oil itself or the color of the reagent for measurement. In addition, the mixed solvent having a strong volatility injected into the container 10, the amount of the mixed solvent is reduced after a certain period of time due to the breathability of the polyethylene material may also cause a measurement error.

In addition, the glass ampoules 30 and 40 specially manufactured to prevent the deterioration of the reagents used in the measurement are not easy to manufacture, and in the case of alcoholic reagents injected into the ampoules 30 and 40, there is a risk of fire in manufacturing. There is a lot of difficulty in making. Further, when the outer wall of the container 10 is pressed, glass fragments of the ampoules 30 and 40 contained in the inner space may penetrate the outer wall of the container 10 and injure a hand.

One object of the present invention is to provide a mechanism for measuring the total value of electrical insulating oil, which presents a new alternative to the conventional method.

Another object of the present invention is to ameliorate the above problems caused by containers or ampoules.

In order to realize the above object, the apparatus for measuring the total value of the electric insulating oil according to an embodiment of the present invention includes a container and a titration liquid. The container has a housing which is formed of a transparent material and forms an inner space of which one end is opened. In the inner space of the housing is accommodated a mixed liquid mixed with a mixed solvent and indicator. The open end is sealed by a stopper. The red chilled liquid is provided for mixing with the mixed liquid and is contained in the container and another container.

According to one aspect of the present invention, the housing is formed of glass.

According to another aspect of the present invention, the receptor has a body in which the internal space is formed. Both ends of the body are sealed by a piston and a sealing cap, respectively, so that the titration liquid contained in the inner space is sealed. The end sealed by the sealing cap of the body has a smaller cross-sectional area than the end where the piston is inserted and sealed.

According to another embodiment of the present invention, a method for measuring a computational value of an electric insulating oil includes (a) filling a mixed solvent and an indicator into a housing made of a transparent material to form a mixed solution, and (b) adding a titration liquid to the housing to be mixed with the mixed liquid. And a step of (c) injecting electrical insulating oil into the housing and calculating a computer value by measuring a change in color.

According to an aspect of the present invention, in the step (b) by pressing the piston accommodated in the body of the receiver is injected into the housing the titration liquid contained in the body.

According to another aspect of the present invention, before pressing the piston to remove the sealing cap for sealing one end of the body.

According to the mechanism for measuring the computational value of the electrical insulating oil and the measuring method according to an embodiment of the present invention, as the housing is formed of a transparent material it is possible to more accurately determine the color change of the solution contained in the housing to improve the reliability of the computation of the acid value do. In addition, when the housing is formed of a material with less breathability, it is possible to prevent the solution from seeping into the housing to reduce the amount of the mixed solvent.

Furthermore, since the mixed solvent and the indicator are stored in the housing mixed, there is no need to make a separate ampoule and there is no inconvenience of mixing them in the field.

In addition, since the receptor is configured in such a way as to pressurize the piston, it is possible to eliminate the inconvenience of breaking the ampoule as in the prior art. One end of the container is equipped with a removable sealing cap to prevent leakage of the titrant contained in the container.

Hereinafter, with reference to the accompanying drawings, a computer-value measuring instrument according to an embodiment of the present invention will be described in detail. However, even different embodiments are given the same or similar reference numerals for the same or similar configuration, and description will not be repeated.

2 is a conceptual diagram for explaining a procedure for measuring a computer value according to the KS standard.

In order to measure the computational value, the computational value test of electrical insulating oil is defined in KS C2101 as the "computerization value test", and the test sequence is as illustrated in the figure. According to the above regulations, the sample to be tested is dissolved in a mixed solvent of toluene and ethyl alcohol. Alkali Blue 6B is used as an indicator. Titration is carried out with a standard aqueous solution of potassium hydroxide, and the acid value (calculated value) is calculated by the following calculation formula.

Where N is the prescribed concentration of 0.05 mol / L potassium hydroxide standard solution

A: Amount of 0.05 mol / l potassium hydroxide standard solution required for titration (ml)

B: Amount of 0.05 mol / l potassium hydroxide standard solution required for the background test (ml)

W: weight of sample (g)

The calculated computer value is usually used as a filtration refining or replacement criterion for electric insulating oil according to the grade shown in Table 1 below.

Result Classification Computer Value Range (mgKOH / g) Results judgment A class 0.02 or less Same quality as new oil B class 0.02 to 0.20 Available C class 0.21 ~ 0.40 Use after filtration or purification D class 0.41 or more substitute

3 is a conceptual diagram illustrating a mechanism for measuring the computer value of electrical insulating oil according to an embodiment of the present invention.

Referring to this figure, the apparatus for measuring the computational value of the electric insulating oil largely includes a container 100 and a container 200.

The housing 110 of the container 100 is a hollow body forming an internal space, and has an open shape at one end thereof. The housing 110 is preferably formed of a transparent material, for example, a glass material. If the glass is made of a material such as a low-permeable vial, the amount of liquid contained in the inner space is absorbed by the housing 110 is preferable because it is small.

In the inner space, the mixed solvent and the indicator are mixed and accommodated in a mixed liquid. The mixed solvent may be a mixture of toluene and ethyl alcohol. The indicator may be used such as alkali blue 6B. In this case, the mixed solvent becomes blue. In the state where the mixed liquid is accommodated in the inner space, the open end of the housing 110 may be sealed by the stopper 120.

The receptor 200 provides a receiving space independent of the housing 110. The accommodation space contains, for example, a standard aqueous solution of potassium hydroxide as a titrant. The receptor 200 includes a body 210 which is a hollow body having a shape extending in the longitudinal direction. The hollow portion of the body 210 forms a stomach receiving space.

Both open ends of the body 210 are sealed by the piston 220 and the sealing cap 230, respectively. The piston 220 may move along the extension direction of the body 210. The sealing cap 230 may be detachably coupled to one end of the body 210. One end of the body 210 to which the sealing cap 230 is coupled is configured to have a smaller cross-sectional area than the other end of the body 210 to which the piston 220 is inserted and sealed. As a result, the titrant provided in the stomach accommodation space may be discharged little by little through one end of the body 210.

4 is a flowchart illustrating a method for measuring a computer value according to an embodiment of the present invention.

3 and 4, first, a mixed solvent and an indicator are poured into the inner space of the housing 110 to mix them. As a result, a mixed liquid is produced.

Next, add the titrant to the gas mixture. To this end, after removing the sealing cap 230, the piston 220 is pressurized so that the appropriate liquid in the accommodation space is discharged through the end where the sealing cap 230 was mounted.

In the mixed state as above, the electrical insulation oil (sample) is added to the housing 110. As electrical insulating oil is added, the color change of the mixed solution in the inner space of the housing 110 is observed. If there is no change in color, the sample can be further mixed.

In this process, the color change is determined to calculate the computer value. The calculated computer value will provide a criterion for determining whether electrical insulating oil can continue to be used based on the criteria shown in Table 1 above.

Apparatus and method for measuring the computational value of the electrical insulating oil as described above are not limited to the configuration and operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

1 is a conceptual view showing a conventional computerized measuring instrument.

2 is a conceptual diagram for explaining the calculation value of the computer value according to the KS standard.

Figure 3 is a conceptual diagram showing a mechanism for measuring the total value of the electric insulating oil according to an embodiment of the present invention.

Figure 4 is a flow chart illustrating a method of measuring a computer value according to an embodiment of the present invention.

Claims (7)

A glass made of transparent material and having a housing defining an inner space of which one end is opened, wherein the mixed liquid containing a mixed solvent and an indicator is contained in the inner space of the housing, wherein the open end is sealed by a stopper; And It is provided for mixing with the mixed solution, and comprises a titration solution contained in the container and other receptors, The housing is formed of glass to more accurately determine the color change of the solution contained in the housing, The container has a body formed with an inner space, the both ends of the body is sealed by a piston and a sealing cap, respectively, so that the titrant contained in the inner space is sealed, And the end portion sealed by the sealing cap of the body has a smaller cross-sectional area than the end portion in which the piston is inserted and sealed. delete delete delete delete delete delete

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