RU219451U1 - Measuring probe for determining the concentration of hydrogen and carbon monoxide dissolved in industrial oils - Google Patents

Abstract

The utility model relates to electrical measuring technology, in particular to sensors for measuring the composition of the environment, and can be used to determine the content of combustible gases (hydrogen, carbon monoxide) in technical oils, in particular, in a transformer oil environment.

The technical result is to expand the possibilities of analyzing technical oil, increasing the accuracy and reliability of measurements of the concentration of gases dissolved in technical oil, in particular in transformer oil.

The technical result is achieved by a measuring probe for determining the concentration of hydrogen and carbon monoxide dissolved in industrial oils, in the form of a tube with holes at one end to ensure the supply of a controlled product, containing a temperature sensor and a hydrogen sensor inside the housing, it contains at least two potentiometric-type electrochemical sensors, one of which has a predominant sensitivity to hydrogen, the second has a predominant sensitivity to carbon monoxide, rigidly connected to the body of the measuring probe by soldering to a metal bar , which, in turn, is rigidly connected in such a way that electrical contact and rigid fixation of electrochemical sensors of the potentiometric type relative to the body of the measuring probe is ensured. 3 ill.

Description

The utility model relates to electrical measuring equipment, in particular to sensors for measuring the composition of the environment, and can be used to determine the content of combustible gases (hydrogen, carbon monoxide) in technical oils, in particular, in a transformer oil environment.

One of the approaches for determining the state of high-voltage oil-filled equipment, in particular power transformers, is the analysis of the content of gases dissolved in transformer oil: H ₂ , CO, CO ₂ , C ₂ H ₆ , C ₂ H ₄ , C ₂ H _{2 ,} etc. dissolved in mineral transformer oil). There are several options for analysis: the release of gases from transformer oil and their further analysis using a chromatograph or gas sensors (sensors), or there are submersible sensors that work directly in the technical oil. The disadvantages of the first type of analysis include the need to separate gases from the oil, which requires more complex and expensive equipment, an increase in the total analysis time, and a decrease in the accuracy of determining the gas content in technical oil. In this regard, preference is given to devices that are able to determine the content of gases dissolved in technical oil, without their release into the gas phase.

An example of a device that determines the presence of gases (hydrogen, carbon monoxide, acetylene, ethylene, ethane, methane, etc.) in transformer oil is the “Analyzer for determining gas in insulating oil” (RF patent No. This device is able to determine the presence of gases dissolved in oil, without the possibility of determining which of the gases is currently present in the oil (hydrogen, carbon monoxide, acetylene, ethylene, ethane, methane, etc.), that is, there is no selectivity to the gases being determined and the device determines the amount of combustible gases. Also in this device, the gas sensing element is separated from the transformer oil by a special gas-permeable membrane, which provides isolation of the oil from direct contact with the gas sensing element.

A more advanced analyzer is the "Device for the analysis of gases in transformer oil" (RF patent No. 2393455, application 2009106943/04 dated February 27, 2009, IPC G01N 7/00), in which the gases to be determined are also separated from the oil using a membrane, however, this device is already able to distinguish the analyzed gases and is able to determine the concentrations of H ₂ , CO, C ₂ H ₂ , etc. separately, and not as a sum of combustible gases. This device uses several types of gas sensors, each with preferential sensitivity to its own gas. The disadvantage of the above devices is that the rate of diffusion of various gases through the membrane is different, which distorts the data on the concentration of gases dissolved in technical oil, and as a result, imposes a limitation on the high accuracy of measurements.

The closest to the proposed is the measuring probe, which is part of the analyzer of technical oils "Hydromer", INTERA, Russia (RF patent No. 178297, application 2017142258 dated 05.12.2017, IPC G01N 27/22, G01N 33/28, H05B 1/02). This device does not have a membrane for separating analyzed gases from technical oil. The gas-sensitive element of this device based on a capacitive sensor (sensor) operates when directly immersed in technical oil and petroleum products, in particular, in transformer oil. The disadvantage of this analyzer is that of the combustible gases that may be contained in the oil, it is able to determine only the hydrogen content. Also, for the operation of the capacitive sensor, as part of this device, it is required to heat the analyzed technical oil to a certain temperature.

The technical problem, which the utility model is aimed at, is to expand the possibilities of analyzing technical oil, increasing the accuracy and reliability of measurements of the concentration of gases dissolved in technical oil, in particular, in transformer oil.

The specified technical task is achieved by the proposed device, due to the fact that in the measuring probe for determining the concentration of hydrogen and carbon monoxide dissolved in technical oils, in the form of a tube with holes at one end to ensure the supply of a controlled product, containing a temperature sensor and a hydrogen sensor inside the housing. The measuring probe contains at least two potentiometric-type electrochemical sensors, one of which has a predominant sensitivity to hydrogen, the second one has a predominant sensitivity to carbon monoxide, rigidly connected to the body of the measuring probe by soldering to a metal bar, which, in turn, is rigidly connected in such a way that electrical contact and rigid fixation of electrochemical sensors of the potentiometric type relative to the body of the measuring probe are provided.

The claimed device is shown in Fig. 1 where:

1 - body of the measuring probe, which is a tube with holes (holes are not shown);

2 - electrochemical sensor of potentiometric type, which has a predominant sensitivity to hydrogen;

3 – electrochemical sensor of potentiometric type, which has preferential sensitivity to carbon monoxide;

4 – temperature sensor;

5 - a metal bar to which the above sensors and a temperature sensor are soldered, or connected by another type of metal connection, which provides an electrical contact that provides rigid fixation of electrochemical sensors of a potentiometric type and a temperature sensor inside the measuring probe body;

6 - electrical wires;

7 – connector for connecting the measuring probe to a device that processes the analytical signal of electrochemical sensors of the potentiometric type and a temperature sensor;

8 - soldering points, or other type of metal connection, which provides electrical contact and rigid fixation of the elements of the measuring probe.

The measuring probe works as follows:

1. The measuring probe is connected via a connector to a device (controller) that processes the analytical signal of electrochemical sensors of a potentiometric type and a temperature sensor;

2. The measuring probe is completely immersed in the analyzed technical oil, while the controller registers the analytical signal of the sensors and the temperature sensor;

3. For some time, the analytical signal of the sensors and the temperature sensor will reach its stationary value;

4. Based on the previously obtained calibration dependences of the concentration of gases (hydrogen, carbon monoxide) dissolved in the technical oil, from the analytical signal of electrochemical sensors of the potentiometric type and the temperature sensor, the content of the determined gases (hydrogen, carbon monoxide) dissolved in this technical oil, in particular in transformer oil, is determined.

Example:

The electrochemical sensors of the potentiometric type included in the measuring probe (hereinafter referred to as sensors) operate as follows. At room temperature, the concentration dependence of the open circuit voltage (Erc) of the sensor, in a certain range of concentrations of the analyzed gas, can be described by an equation similar to the Nernst equation:

E _con. = E ₀ + k×lg[C _gas ], where:

E _con. is the open circuit voltage of the sensor at a given concentration of the gas to be determined;

E ₀ is the open circuit voltage of the sensor in the absence of the gas to be determined;

k is the coefficient of sensor sensitivity to the gas to be determined, shows the change in Erc of the sensor when the concentration of the gas to be determined changes by 10 times;

C _gas - concentration of the determined gas.

The response of the measuring probe to various gases (hydrogen, carbon monoxide) dissolved in transformer oil is shown in Fig. 2, which shows the change in Erc of electrochemical sensors of the potentiometric type, immersed in GK grade transformer oil, relative to the initial Erc (E ₀ is Erc, sensors before the input of the gas to be determined into the oil) when they react to 100% CO or 100% H ₂ above the oil. According to the coefficients of gas dissolution in transformer oil: for carbon monoxide, this coefficient is 0.11, and for hydrogen 0.5 (Davidenko I.V., Kuzina T.S., On the issue of gas solubility in transformer oil // Conference of young scientists - 2017 Ural ENIN, FGAOU VO "UrFU"). Accordingly, to establish the concentration of these gases in transformer oil, it is necessary to multiply the concentration of gas above the oil by this coefficient. To create a certain concentration of hydrogen and carbon monoxide above the oil, a mixture of these gases with argon was prepared in advance, after which it was passed through GK grade transformer oil for a long time. As the transformer oil is saturated with the gas mixture, the equilibrium value of Erc of each of the sensors that make up the measuring probe is established. On FIG. 3 shows the dependence Econ. for two sensors (the first has a predominant sensitivity to hydrogen (sensor for H ₂ ), the second has a predominant sensitivity to carbon monoxide (sensor for CO)), which are part of the measuring probe, on the concentration of carbon monoxide dissolved in transformer oil. According to the data from Fig. Figure 3 shows that the CO sensor has a significantly higher k (sensitivity coefficient of the sensor to the gas being determined) compared to the H ₂ sensor when determining the concentration of carbon monoxide dissolved in GK grade transformer oil. Knowing such dependence Ekon. for sensors that are part of the measuring probe, the concentration of gases to be determined (hydrogen, carbon monoxide) can be determined from the concentration of hydrogen dissolved in transformer oil (the sensitivity coefficients of the sensors will differ).

When determining CO: k(sensor for CO) > k(sensor for H ₂ ).

When determining H ₂ : k(sensor for CO) < k(sensor for H ₂ ).

In addition to the difference in the sensitivity coefficients of the sensors in the determination of different gases (hydrogen, carbon monoxide), the relative change in Erc (ΔE = Econ. - E ₀ ) of the sensors also differs when they operate in a transformer oil environment depending on the gas being determined (Fig. 2).

The construction of several series of similar dependences (Fig. 3), as well as the dependences of the change in Erc sensors from time to time depending on the gas being determined (Fig. 2), with the correct processing of analytical signals received from the measuring probe by an external device, makes it possible to establish the concentrations of carbon monoxide and hydrogen dissolved in transformer oil.

Thus, the claimed device is capable of determining the concentration of carbon monoxide and hydrogen dissolved in technical oil, in particular in transformer oil.

Claims (1)

Measuring probe for determining the concentration of hydrogen and carbon monoxide dissolved in industrial oils, in the form of a tube with holes at one end to ensure the supply of a controlled product, containing inside the body a temperature sensor and a hydrogen sensor, characterized in that it contains at least two electrochemical sensors of a potentiometric type, one of which has a predominant sensitivity to hydrogen, the second has a predominant sensitivity to carbon monoxide, rigidly connected to the body of the measuring probe by soldering to a metal bar , which, in turn, is rigidly connected in such a way that electrical contact and rigid fixation of electrochemical sensors of the potentiometric type relative to the body of the measuring probe is ensured.