RU2810231C1 - Use of dimethyl ether formed during regeneration of aluminium silicate adsorbents as indicator substance to detect leaks in shut-off valves - Google Patents

Abstract

FIELD: inspection devices.

SUBSTANCE: inspecting devices for tightness that can be used to monitor tightness of shut-off valves of an installation for adsorption-type unit providing gas treatment before transportation, filled with adsorbents containing aluminium oxide. Concentration of the indicator substance in natural gas on both sides of taps and valves is compared. In this case, dimethyl alcohol is used as an indicator substance, which is formed during regeneration of adsorbents from methanol contained in natural gas.

EFFECT: monitoring tightness of the shut-off equipment of an adsorption-type unit for natural gas treatment before transportation, filled with adsorbents that contain aluminium oxide.

1 cl, 2 dwg

Description

The invention relates to the field of research into the tightness of shut-off valves of gas pipelines in adsorption-type gas treatment plants for transport (hereinafter referred to as GTP), which use aluminosilicate adsorbents (zeolites, silica gel adsorbents of an amorphous structure containing SiO ₂ ) and implement high-temperature TSA (temperature swing adsorption) regeneration using an indicator gas.

An important requirement for shut-off valves of main gas pipelines and, in particular, UPGT for offshore sections of gas pipelines, is to ensure the tightness of the valve when closed. In this regard, to ensure the quality of the transported gas, as well as to prevent emergency situations, periodic monitoring of the tightness of the shut-off valve is necessary.

Known methods for checking tightness using marker substances in the composition of tracer gases involve introducing them into the flow of transported gas and subsequent determination of these substances using instrumental methods.

A known method consists of injecting a portion of tracer gas into the flow of transported gas at the entrance to the shut-off and control valve (hereinafter referred to as the SVR) and recording the time it takes for a portion of tracer gas to travel from the point of its injection to the receiving point (Patent RU 2317482 C1, published 02.20.2008 ), which allows you to periodically check the shut-off parameters of the control valve and its tightness. A tracer gas dispenser with an electric outlet and an injector is proposed to be installed inside the main gas pipeline in front of the control valve.

A method for monitoring the tightness of shut-off valves of natural gas pipelines is described (Patent RU 2309323 C1, published on October 27, 2007), which involves using halogens as an indicator gas: freon or carbon tetrachloride vapor, and tungsten, or copper, or platinum. It is proposed to use two gas parameter sensors connected by outputs to an information processing unit and a recorder; the device additionally contains a tracer gas dispenser with an electric injector located inside the main gas pipeline in front of the control valve upstream of the transported gas, while the gas parameter sensors are made in the form of tracer gas concentration sensors , located on opposite sides of the air defense system at known distances from the injector.

The disadvantage of the above methods is the need to introduce foreign components into the natural gas flow, which include marker substances in tracer gases, as well as the need to install a dosing device inside the pipeline, which involves changing the design and periodic maintenance of the dosing device. In addition, the reliable operation of dosing devices can be harmed by high temperatures in the regeneration gas line up to 290°C and high concentrations of water vapor, hydrogen sulfide, and suspended particles of aluminosilicate adsorbent.

As a prototype, a method was adopted for determining the amount of product flowing through a closed shut-off valve on a pipeline, including pulsed injection of a fixed volume of tracer into the pipeline from the side of higher pressure in front of the shut-off valve, taking a sample of the product from the pipeline after the shut-off valve from the side of lower pressure, measuring the concentration of the tracer in the selected sample with an analyzer and determination of the amount of flowing product (Fifth anniversary international business meeting "Diagnostics-95". Reports and communications. Volume 1. Diagnostics of pipelines, Yalta, April 1995 - M., 1995, pp. 103-107).

This invention is aimed at achieving a technical result, which is to ensure the quality of export gas supplied through offshore sections of gas pipelines, as well as the safety of operation of pipeline shut-off valves at an adsorption-type UPGT by identifying at an early stage the lack of tightness of the shut-off valve (or gate) of the shut-off valves using indicator gas. Distinctive features of the proposed method are:

1) the use of an indicator substance - dimethyl ether (hereinafter - DME), which is present in the regeneration gas of the adsorption type UPGT, i.e. which does not need to be artificially created and introduced into the gas in the form of foreign impurities;

2) no need to install additional special devices on the pipeline for dosing tracer gas.

DME is formed as a result of the reaction of intermolecular dehydration of methyl alcohol in the regeneration mode of aluminosilicate adsorbents in installations for the preparation of natural gas for transport along offshore sections of adsorption-type gas pipelines. The chemical reaction equation for intermolecular methanol dehydration is shown in Scheme 1.

Such UPGTs are used for more complete removal of water vapor, liquid hydrocarbons, methanol and other substances. The installation contains several adsorbers filled with silica gel adsorbents. After saturation of the adsorbents in the adsorption mode, the adsorber switches to the high-temperature regeneration mode (280-290°C) [1], as a result of which, in addition to the desorption of substances, chemical reactions simultaneously occur with the formation of substances that were initially absent in ordinary natural gas [2]. These substances include DME, which is formed from methanol adsorbed from gas. Compared to other substances formed in the regeneration mode, DME has the qualities of an indicator substance: it is not present in the composition of the controlled volume of gas (gas prepared for transportation), it has a gaseous state of aggregation under test conditions (boiling point minus 24.9 ° C), not causes corrosion of pipelines and shut-off valves, does not react with natural gas components.

The raw material for the formation of DME is methanol, the vapors of which are usually present in natural gas due to its widespread use as an inhibitor of hydrate formation under conditions of low temperatures of gas production and transportation [3-5]. Methanol vapor is not completely removed from natural gas and is transported through gas pipelines and gas distribution systems. When preparing gas using aluminosilicate adsorbents, including silica gel adsorbents that contain aluminum oxide [6], selective extraction of components from the gas flow occurs. The most intensively extracted components are those that are most firmly held by sorption-active centers, the role of which in aluminosilicate adsorbents is played by hydroxyl groups: ≡Si-OH and =Al-OH. The strongest are the hydrogen bonds that form between the adsorbent and water; methanol occupies an intermediate position between water and hydrocarbons in terms of bond strength [2]. Strong hydrogen bonds allow methanol to concentrate in the adsorber in a compact zone, which promotes the occurrence of the chemical dehydration reaction.

In addition to the presence of reactants and high temperature, to create conditions for the reaction of intermolecular dehydration of methanol with the formation of DME, a catalyst is required, which is an aluminosilicate adsorbent [7]. The temperature at which the reaction proceeds at a rate sufficient for practical purposes (catalyst ignition temperature) is in the range of 150-160°C [8].

The lack of tightness of the shut-off valves separating the flows of regeneration gas and prepared gas can be determined by the presence of dimethyl ether (an indicator substance) in the latter using gas chromatography. The flow of regeneration gas into the adsorption line through leaky shut-off valves can occur due to the pressure difference in these lines of 0.15 MPa existing at the gas treatment unit. Figure 1 shows a diagram showing the conditions for determining the tightness of shut-off valves, where Preg is the pressure of the regeneration gas, Rads is the pressure of the gas prepared for transportation.

The determination of DME concentration is carried out by gas chromatography using hardware and software complexes based on chromatographs equipped with a flame ionization detector and a capillary column similar or similar in characteristics to HP-1 (50 m × 0.32 mm × 0.25 μm). Conditions for gas chromatographic separation: carrier gas (argon, nitrogen or helium), carrier gas speed 16-25 cm/sec, division of the carrier gas flow when introducing a sample 1:20, sample volume 1.0 ml, detector temperature 250°C, temperature program of the column thermostat: 50°C for 7 minutes, temperature increase 10°C/min to 230°C, analysis time 35 minutes.

To calibrate the detector, a state standard sample of natural gas simulator was used. In fig. Figure 2 shows a schematic arrangement of the components of regeneration natural gas and dimethyl ether (DME) on a fragment of the chromatogram as a result of analysis by gas chromatography.

Taking into account the physical properties of DME, in particular, the boiling point value of minus 24.9°C, it is recommended to perform leak tests using the proposed method in the warm season.

INFORMATION SOURCES:

1. Regulations for the operation of silica gel at gas treatment plants for transport (UPGT) of the Portovaya CS, Krasnodarskaya CS and Kazachya CS: approved 03/05/2018 / Department No. 308 of PJSC Gazprom. - St. Petersburg, 2018. - 18 p.

2. Vasyukov D.A. Features of the flow of chemical processes in various technologies for the regeneration of adsorbents at gas treatment plants for transport / D.A. Vasyukov, S.G. Shablya, V.P. Petruk [etc.] // Gas industry. - 2021. - No. 6. - P. 64-70.

3. STO Gazprom 2-2.3-143-2007. Instructions on the procedure for receiving from suppliers, transporting, storing, dispensing and using methanol at production, transport and UGS facilities of OJSC Gazprom. Gazprom VNIIGAZ LLC. - M.: ZAO Publishing House Polygraphy, 2007. - 30 p.

4. Tukhbiev R.F. The use of methanol in the oil and gas industry [Electronic resource] / R.F. Tukhbiev, R.A. Kemalov // Correspondence electronic conferences - Access mode: http://econf.rae.ru/article/9615 (11/15/2022).

5. Istomin V.A. Technologies for preventing hydrate formation in field systems: problems and prospects [Electronic resource] / V.A. Istomin, P.M. Minigulov, D.N. Gritsishin, [etc.] // Gas chemistry. - 2009. - No. 6. - P. 32-40. Access mode: https://cyberleninka.ru/article/n/tehnologii-preduprezhdeniya-gidratoobrazovaniya-v-promyslovyh-sistemah-problemy-i-perspektivy/viewer (11/15/2022).

6. Method of varying the methanol content during regeneration of the adsorbent for natural gas drying: Patent No. 2771560 Ros. Federation, IPC B01D 53/26 B01J 20/34 B01J 20/10 / Vasyukov D.A., Shablya S.G., Petruk V.P., Rudenko A.V., Kolychev I.A., Zavalinskaya I.S. .; applicant and patent holder Gazprom Transgaz Krasnodar LLC. - No. 2020121923; application: 06/26/2020; publ. 05/05/2022, Bulletin. No. 13. - 2 s.

7. Temerdashev, Z.A. Catalytic activity of silica gels modified with aluminum oxide under conditions of conversion of methanol into dimethyl ether / Z.A. Temerdashev, A.S. Kostina, A.V. Rudenko, I.A. Kolychev, A.M. Vasiliev // Journal of Applied Chemistry. - 2021. - T. 94. - No. 5. - pp. 570-579.

8. Temerdashev, Z.A. Influence of regeneration conditions of aluminosilicate adsorbents on the dehydration of methanol extracted from natural gas / Z.A. Temerdashev, A.V. Rudenko, I.A. Kolychev, A.S. Kostina // Ecology and industry of Russia. - 2020. - T. 24. - No. 8. - pp. 17-21.

Claims (1)

A method for monitoring the tightness of shut-off valves of an adsorption-type natural gas preparation installation filled with adsorbents containing aluminum oxide - zeolites and amorphous aluminosilicates, by comparing the concentration of an indicator substance in natural gas on both sides of taps and valves, characterized in that as The indicator substance is dimethyl ether, which is formed during the regeneration of adsorbents from methanol contained in natural gas.