RU171673U1 - DEVICE FOR MEASURING SMALL CONCENTRATIONS OF WATER IN WET GAS MEDIA - Google Patents

Abstract

This utility model relates to a technique for measuring gas humidity, can be used to control the physicochemical properties of gas in the gas processing industry, petrochemicals, and other industries and is aimed at improving the accuracy of measuring small concentrations of water in an analyzed wet gas environment (mainly in the range from 0 up to 3000 ppm) with continuous monitoring. The specified technical result is achieved by the fact that in the device for measuring small concentrations of water in wet gas environments, the sealed vessel 1 with a sample of 12 calcium carbide is equipped with a pipe 7 for connecting to the feed channel of the analyzed wet gas medium and a pipe 9 for connecting to the channel 4 of the removal of acetylene formed in the process of interaction of moisture of the analyzed moist gas environment with calcium carbide, in the analytical unit 5 - gas chromatograph. By the amount of acetylene leaving the sealed vessel 1, and by the calibration characteristic of the device, the concentration of water in the analyzed moist gas medium is established. 1 s.p. f-ly, 1 ill.

Description

This utility model relates to a technique for measuring gas humidity and can be used to control the physicochemical properties of gas in the gas processing industry, petrochemicals, and other industries where it is necessary to measure small concentrations of water (mainly in the range from 0 to 3000 ppm) when transporting natural gas, in product quality control systems in the oil and gas industry, in commercial metering stations, in systems for measuring the quantity and quality indicators of gas and liquefied petroleum s gases in gas mains.

A known absorption method for determining water vapor content and moisture dew point, which consists in absorbing water vapor with anhydrous diethylene glycol and subsequent determination of water bound diethylene glycol by titration with Karl Fischer solution or gas chromatography method (GOST 20060-83 Natural combustible gases. Methods for determining the content of water vapor and dew point moisture) [1].

The disadvantage of this method is that it is used to determine water vapor when their content in the gas is more than 100 mg / m ³ , has a large error.

A known device for measuring soil moisture, made in the form of a hermetically sealed and connected to a pressure gauge vessel for hanging samples of the test soil and calcium carbide, in which, when the water contained in the sample of the soil and calcium carbide react, a chemical reaction occurs with the release of acetylene, which increases in the chamber pressure reflected by the pressure gauge. According to the resulting value of the pressure in the chamber, the desired concentration of water in the test soil is calculated, taking into account the molar ratios of the starting compounds and the products of the chemical reaction (Copyright certificate for the invention SU No. 79680, IPC G01N 33/24, publ. 01.01.1949) [2 ], (prototype method).

The disadvantages of the device are the inability to continuously measure the moisture content of the product, the accuracy of measuring the water concentration depends on the accuracy of measuring the weight of the soil, pressure, temperature, completeness of the chemical reaction.

The technical result of this utility model is the possibility of continuous measurement of small concentrations of water in the flow of the analyzed moist gas environment within the limits provided by a sample of calcium carbide, increasing the accuracy of measuring small concentrations of water in the analyzed wet gas environment.

The technical problem is solved by a device for measuring small concentrations of water in moist gas environments, made in the form of a sealed vessel, with a calcium carbide sample poured into the cavity of the sealed vessel, in which the aforementioned sealed vessel is equipped with an inlet pipe for connecting to the supply channel of the analyzed wet gas medium and an outlet pipe for connecting to the drainage channel of the moisture of the analyzed moist gas medium formed during the interaction of moisture with calcium carbide acetylene in the analytical unit. In addition, the technical problem is also solved by the fact that the said sealed vessel is installed in the cavity of the working chamber of the thermostat.

The essence of the utility model is that, in contrast to the prototype, the analyzed moist gas environment is continuously, within the limits provided by the weighed portion of calcium carbide, fed into a sealed vessel, interacts with calcium carbide, and the resulting acetylene through the outlet channel enters the analytical unit. The content of acetylene in the gas leaving the sealed vessel is proportional to the concentration of water in the analyzed moist gas environment. By the amount of acetylene determined by the analytical unit, by simple calculation, the water content in the analyzed moist gas medium is determined. Maintaining the required temperature in the working chamber of the thermostat ensures a constant temperature of the sealed vessel and the reaction conditions under which only the pressure and flow rate of the analyzed moist gas environment affect the reaction rate and output.

The drawing shows a diagram of a device for measuring small concentrations of water in moist gas environments.

The measurement device consists of a sealed vessel 1, a thermostat 2, a channel 3 for supplying an analyzed wet gas medium to an airtight vessel 1, a channel 4 for removing the moisture of an analyzed wet gas medium formed during the interaction of moisture with calcium carbide acetylene into an analytical unit 5.

The sealed vessel 1 is made with an inlet valve 6 with a pipe 7 connecting the sealed vessel 1 with a supply channel 3 of the analyzed wet gas medium, and with a tap 8 of the outlet through the pipe 9 into the channel 4 of the formed acetylene. The sealed vessel 1 is equipped with a pipe 10 for filling in the cavity 11 of the sample 12 of calcium carbide. To stabilize the process of producing acetylene, a sealed vessel 1 is installed in a sealed working cavity 13 of the thermostat 2.

A filter 14 is installed on the channel 3 for supplying the analyzed wet gas medium to the sealed vessel 1 to protect the cavity 11 from mechanical impurities. A filter 15 is installed on the channel 4 for removing acetylene from the sealed vessel 1 to prevent the removal of calcium carbide from the sealed vessel 1, a pressure regulator 16, and an analytical unit 5, for example, a gas chromatograph. A bypass line 17 with a control valve 18 and a gas flow meter 19 is connected to the acetylene outlet channel 4.

A device for measuring small concentrations of water in moist gas environments works as follows. Before starting the measuring device in operation, the device is calibrated, for which a wet gas microflow source (not shown) is connected to the filter 14 installed on the supply channel 3 of the analyzed wet gas medium in the sealed vessel 1, and wet gas samples with various humidity (at least five samples). When flowing through a sealed vessel 1, the water contained in the gas irreversibly reacts with calcium carbide in the sealed vessel 1, forming acetylene. The content of acetylene leaving the sealed vessel 1 is proportional to the concentration of water in the gas. The amount of acetylene released during each measurement is recorded using a gas chromatograph, and the corresponding signal is obtained in the form of acetylene peaks in the chromatogram. The obtained calibration characteristic then allows measuring the humidity of the gaseous medium by proportionally converting the peak area of acetylene to the concentration of water. After calibrating the device, the source of the microflow of the wet gas (not shown) is disconnected. The device is ready to take measurements.

To measure small concentrations of water, the channel 3 for supplying the analyzed wet gas medium to the sealed vessel 1 is connected to the sampling device of the pipeline (not shown) for the wet gas medium. After passing the selected sample of the analyzed moist gas medium through the sealed vessel 1 and the acetylene formed as a result of the reaction through the analytical unit 5 (gas chromatograph), the peak of acetylene is established and the concentration of water in the analyzed wet gas medium is determined from the available chromatogram. The stability of the reaction of acetylene production is provided by thermostat 2.

The proposed utility model improves the accuracy of measuring small concentrations of water in the analyzed moist gas environment due to the high selectivity and specificity of the applied reaction of calcium carbide with water, guaranteed the absence of the reaction product (acetylene) in the original test medium, and the absence of acetylene adsorption effects (unlike water) on internal surfaces of the system, the ability to measure trace acetylene concentrations with simple and common detectors, which will allow the efficient use of devices in measuring small concentrations of water in various industries.

Claims (2)

1. The device for measuring small concentrations of water in moist gas environments, made in the form of a sealed vessel filled with a sample of calcium carbide poured into the cavity of the sealed vessel, characterized in that the said sealed vessel is equipped with an inlet pipe for connecting to the feed channel of the analyzed wet gas medium and an outlet pipe for connecting to the drainage channel of the moisture of the analyzed moist gas medium formed during the interaction of moisture with calcium carbide acetylene in the analytical unit. 2. The device according to claim 1, characterized in that the said sealed vessel is installed in the cavity of the working chamber of the thermostat.

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