Газ өнеркәсібіндегі заманауи энергия жағынан тиімді және экологиялық қауіпсіз технологиялар

Мұқаба


Дәйексөз келтіру

Толық мәтін

Аннотация

«Жасыл» энергетиканың қарқынды дамуын ескере отырып, оның жаңартылатын энергия көздеріне көшуіне байланысты, барлық елдер мен ірі трансұлттық мұнай-газ корпорациялары негізінен, әлемдік экономиканың көмірсутек ресурстарына деген қажеттілігінің жаһандық сценарийлерін болжауға көбірек көңіл бөлуде. Бұл болжамдар одан әрі даму стратегияларын анықтайтын негізгі нұсқаулық болып табылады. Табиғи көздерден алынатын газ, әлемдік энергетикада және отынның халықаралық балансында шешуші рөл атқарады. Газды қайта өңдеу зауытын салудың басты міндеті-қазақстандық тұтынушыларды сапалы тауарлық газбен қамтамасыз ету және өз ресурстары есебінен газбен жабдықтаудың тұрақтылығын арттыру. Дайын өнімнің техникалық стандарттарына сәйкес болу үшін газды қайта өңдеу зауыттарының технологиялық тізбектері кіріс сепараторларын, газ кептіргіштерді, күкіртті күкіртсіздендіру және күкірт алу қондырғыларын, газ фракциялау жүйелерін, сондай-ақ қышқыл (шикі) газды айдау жүйесін қамтуы тиіс. Аталған мақалада тауарлық газды өндіру процестерінде қолданылатын газды дайындаудың жаңа технологияларына шолу жасалған. Абсорбциялық, адсорбциялық және мембраналық әдістерді қоса алғанда, газды күкіртсіздендіру жүйелерінің жіктелуі мен қысқаша сипаттамалары берілген. Кептіру жүйелерінде қолданылатын цеолиттердің әртүрлі түрлері де ұсынылған. Ерекше назар, шикі газ айдау процестеріне аударылады.

Толық мәтін

Introduction

One of the characteristic features of gas production in Kazakhstan is that at most large fields gas is extracted as a by-product from the oil-gas mixture. This leads to dependence of gas production volumes on oil recovery rates.

More than 95% of all explored gas reserves are concentrated in the western regions of the country, with over 85% of these reserves located in large oil and gas fields such as Kashagan, Tengiz, Korolevskoye and Zhanazhol, as well as in the Karachaganak and Imashevskoye oil and gas condensate fields. The reserves of the largest fields are as follows: Kashagan – 1,353 billion m³, Karachaganak – 741 billion m³, Tengiz – 510 billion m³1.

Design project of gas processing units strongly depends on gas production compositions, product specifications and environmental considerations. The crude feed from Field to Gas Plant contains solids, hydrocarbons (HC) and H2S, water.

During gas treatment, the raw gas is subject to purification and drying.

The facilities of the gas treatment processing system can be conditionally divided into 3 components [1]:

  • Field and Gathering System;
  • Onplots and Utilities;
  • Offplots and Export Systems.

The gas treatment process flow diagram may include the following equipment:

  • Separation Unit;
  • Desalination Unit;
  • Stabilization Unit;
  • Gas compression Unit.
  • Blending and distribution of the High-Pressure (HP) sour gas (SG) stream (which is the product stream from Separation and Stabilization Units) between the gas sweetening system and SG Injection (SGI) facility;
  • Sulfur recovery unit (Claus process);
  • Tail gas cleanup unit, including SCOT (Claus Off-Gas Treating Process)/Sulfren/Beavon/Superclaus and etc. processes [2–3];
  • HC liquids recovery unit;
  • Sour (Formation) water treatment unit.

On flowcharts for gas treatment is shown in Fig. 1.

 

Figure 1. General process flow diagram of the Gas Processing Plants CPC –Pipeline; DE – Design Engineering; COS – Carbonyl sulfide; RSH – Mercaptans

CPC –Pipeline; DE – Design Engineering; COS – Carbonyl sulfide; RSH – Mercaptans

 

At the gas treatment unit, crude oil undergoes separation, desalting and oil stabilization. Gas is separated from oil in three consecutive separators (high, medium and low pressure).

The high-pressure crude gas separated from the oil is sent to acidic components (H2S and CO2) gas removal with amine and amine regeneration.

The hydrogen sulfide-saturated amine solution from the amine treatment unit is regenerated to release hydrogen sulfide (by stripping) and recycle the recovered amine. SG with high hydrogen sulfide content coming out of the amine regenerator is sent to the sulfur recovery unit. The sweet high-pressure gas from the amine treatment unit is sent to a fractionation unit to produce liquefied petroleum gas (LPG) and sales gas, which is sent to the gas pipeline.

Inlet separation

Inlet separation units perform several important functions:

  • Stabilization of crude and gas feeds from the Field;
  • Separation of crude into gas and liquid, which are recombined in the HP Separator;
  • Solids from the Slugcatcher will be removed Introduction

The facilities of the gas treatment processing system can be conditionally divided into 3 components [1]:

  • Field and Gathering System;
  • Onplots and Utilities;
  • Offplots and Export Systems.

The gas treatment process flow diagram may include the following equipment:

  • Separation Unit;
  • Desalination Unit;
  • Stabilization Unit;
  • Gas compression Unit.
  • Blending and distribution of the High-Pressure (HP) sour gas (SG) stream (which is the product stream from Separation and Stabilization Units) between the gas sweetening system and SG Injection (SGI) facility;
  • Sulfur recovery unit (Claus process);
  • Tail gas cleanup unit, including SCOT (Claus Off-Gas Treating Process)/Sulfren/Beavon/Superclaus and etc. processes [2–3];
  • HC liquids recovery unit;
  • Sour (Formation) water treatment unit.

On flowcharts for gas treatment is shown in Fig. 1. before Non-Turnaround Vessel Inspection.

The slugcatchers can be of two types [5]:

  • Vessel type;
  • Finger type.

The Slugcatcher operates at 68 barg and 50–70 °C under normal operating conditions.

Vessel type slugcatcher are simple vessel for separation of two phases. Although the separation efficiency of the vessel is not critical for the slugcatcher, the vessel volume is important.

At the gas treatment unit, crude oil undergoes separation, desalting and oil stabilization. Gas is separated from oil in three.

The vessel must be large enough to accommodate large liquid slugs that form in the pipeline, especially when the pipeline pigging.

Since oil and gas pipelines typically have very high pressures, a large vessel must be designed for high design pressures (Fig. 2).

 

Figure 2. Vessel type slug catcher [6]

 

Finger type slugcatchers solve the economic problem of having to design a large buffer volume for high design pressures. To create a buffer volume, multi-pipe slugcatchers use large diameter pipe pieces instead of a conventional vessel. Since a pipe is easier to design to withstand high pres-sures than a vessel, this design offers advantages in terms of pressure resistance. However, a large number of pipes are required to provide sufficient volume, which increases the footprint of the finger pipe slugcatchers (Fig. 3).

 

Figure 3. Finger type slugcatcher [7]

 

The natural gas after the slugcatchers moves to separation to remove free water, next gas goes to gas sweetening unit.

Gas dehydration

Produced natural gas contains moisture, which adversely affects the processing and transportation processes, in particular, some hydrocarbons in the presence of water can form hydrate deposition, which leads to a reduction in the cross-sectional area of pipelines and valves, which can, in the case of complete blockage of the cross-section, cause an emergency situation [4].

Water from gas may be removal through physical methods such as adsorption, absorption, memb-ranes, condensation with using cold, also chemical methods (CaCl2, etc.) and their different combinations.

Following methods, ordered by popular appeal in this list, can be used for commercial purposes:

  • Absorption – glycol dehydration [8–11];
  • Adsorption – zeolites, silicagels [12];
  • Condensation – process with injection of hydrate inhibitors [4];
  • Membranes – based on polymers or glassy polymers [13];
  • Chemical method – using hygroscopic reagents [14]. Most units worldwide are based on the first two methods (Fig. 4).

Process flow diagram of gas production units with combined gas drying processes using molecular sieves is shown in Fig. 5.

 

Figure 4. Process flow diagram of gas production units with combined gas drying processes. NGL – Natural Gas Liquid

NGL – Natural Gas Liquid

 

Figure 5. Process flow diagram of gas production units with combined gas drying processes using molecular sieves

 

The adsorption method of drying is based on the use of solid adsorbents. The role of solid adsorbents can be used zeolites, silica gels. The selectionof adsorbents depends on the gas compositions, as it may contain substances that have a negative effect on the adsorbent, such as a higher hydrocarbon.

Tab. 1 summarizes the main brands of zeolites adsorbed by them [15–16].

There are chemical agents that ensure almost complete gas drying [16]. These agents are very difficult or even impossible to regenerate [17].

 

Table 1. Basic brands of industrial zeolites

#

Zeolites
grades

Pore size,
 Å

Sorbates

1

3A

3

small molecules – H₂O, NH₃

2

4

small molecules – H₂O, NH₃, H₂S, CO₂,
 C₂H₄, C₂H₆, C₃H₈

3

5

small molecules – H₂O, NH₃, H₂S, CO₂,
 C₂H₄, C₂H₆, C₃H₈, C₃………C₂₂, CCl₂F₂, C₂H₅OH

4

13Х

10

small molecules – H₂O, NH₃, H₂S, CO₂,
 C₂H₄, C₂H₆, C₃H₈, C₃………C₂₂, CCl₂F₂,
 C₂H₅OH, ethanol homologues

 

Gas sweetening process

For gas sweetening usually, next technologies are used:

  • Regenerative absorption;
  • Regenerative adsorption;
  • Separation of sour gas on membranes;
  • Non-generative approaches.

The select of the Best Available Technique depends on a number of factors:

  • Concentration of sour gas components in the feed-stock;
  • Feedstock flowrate;
  • Process pressure;
  • Environmental requirements and others.

To achieve sales gas specifications, a combination of several methods is used in some cases [18].

Absorption processes for gas sweetening remain the most cost-effective for large-capacity sales gas production. There are many variations processes, organized into three groups [19–20]:

  • Chemical absorption processes;
  • Physical absorption processes;
  • Processes with physical-chemical absorbents.

In chemical absorption processes, sour gases dissolve in the absorbent and then react chemically with it.

Absorbents interact with hydrogen sulfide, carbon dioxide and, to some extent, with carbon disulfide (CS2) to form water-soluble salt and water.

The best-known amines are used following gas sweetening processes:

  • Monoethanolamine;
  • Diethanolamine;
  • Triethanolamine;
  • Diglycolamine;
  • Diisopropanolamine;
  • Methyldiethanolamine.

Mono- and diethanolamine have the maximum practical application.

The most common physical solvents for gas sweetening processes are Polyethylene Glycol Dimethyl Ether, methanol, N-methyl-2-pyrrolidone and propylene carbonate [21–22].

As noted in articles [23–24], physical absorbents have a lower specific flow rate in relation to the gas flow rate compared to amine solutions. Fine gas cleaning by physical solvents will require the addition of additional treatment steps.

Absorption processes for the gas treatment are described in more detail in articles [25–27].

The main sweetening processes of natural gas are shown in Tab. 2.

In the production sales gas as fuel, the gas from sweetening unit must be subjected to fine gas cleaning by additional processes [28].

 

Table 2. Absorption treatment of gases from sour compounds

Name of
the process

Processes

Advantages

Disadvantages

Chemical
absorption

Absorption by amines,
Flexorb®, Benfield®

Low degree of equipment corrosion

Low efficiency of mercaptan extraction.
Formation of heat stable salts
with carbon dioxide

Physical
 absorption

Selexol®, Fluor
Solvent®, Purisol®

Selective gas treatment from hydrogen sulfide and other sour gas components

Heavy energy consumption for
absorbent regeneration

Hybrid
absorption

Sulfinol®, Ucarsol®,
 Ecosorb®

Absorbents treatment of gases from hydrogen sulfide

Heavy energy consumption for
absorbent regeneration

 

Gas injection

Main process flows of the gas injection unit:

  • HP raw gas to the inlet of the injection compressor;
  • Compressed HP raw gas for injection;
  • Sales gas to feed the turbine and seal gas compressors;
  • Hydrocarbon condensate to field metering stations.

Since 2004, Kazakhstan has been implementing gas injection programs using associated petroleum

gas to maintain reservoir pressure [29–31]. The projected volumes of sour gas injection will be 31.7 billion m³ in 2025 and 41 billion m³ in 20302.

The associated raw gas intended for injection is dried to remove all water and heated so that the gas temperature at the compressor inlet is above the hydrocarbon dew point. During normal operation, this prevents the formation of hydrocarbon liquid in the pipeline and deposits in the sludge trap on the compressor station raw gas line. However, condensation cannot be avoided during start-up, shutdown and other cases where the pipeline temperature drops. Therefore, in such cases, provision is made to remove the sulfur-containing liquid if necessary. Liquid condensate accumulated at the compressor station is returned back to processing through the central field manifold. Injection compressor including the three-stage turbine-driven injection compressor, the interstage knockout drums and air-cooled heat exchangers, seal gas compressor system and fuel gas conditioning skid.

The gas injection process is shown in Fig. 6.

 

Figure 6. General block diagram of gas injection process

 

Injection of gas back into the oil reservoir allows increasing oil recovery. Operation of the SGI at the Tengiz field provides about 25% of the total Tengizchevroil oil production [32].

Gas injection also ensures maintenance of reservoir pressure, while the need for associated gas utilization (processing, storage and sale of by-products, sulfur recovery from hydrogen sulfide) disappears3.

Conclusion

This scientific article analyzes modern gas treatment and dehydration technologies used in natural gas production process. The paper classifies and briefly reviews the characteristics of purification systems, such as absorption, adsorption and membrane systems, and considers different types of zeolites used in dehydration plants. A special place in the study is given to gas injection technologies.

It is shown that energy efficiency of natural gas purification and dehydration processes depends on the use of a particular type of adsorbent, and also depends on the conditions of the process, primarily on the water content of the gas entering the plant and the thermal regime of the dehydration process.

The kinetics of the process is affected by adsorbent granule sizes, also resistance of the adsorbent layer increases. Small adsorbent particle size improves the kinetics process, but at the same time upgrades the layer resistance.

The most important parameter determining the absorption capacity of the desiccant layer is the relative gas humidity. The higher the relative humidity, the higher the adsorbent activity. At longer contact time “gas-adsorbent”, and, consequently, lower gas velocity, the depth of drying and the duration of the layer operation up to the moment of slip increase.

For the achievement of the very low dew point of the dehydrated gas, deeper adsorbent regeneration is required, which is realized by using desorption process of the dry gas.

ADDITIONAL INFORMATION

Funding source. This study was funded by the Committee of Science of the Ministry of Science and Higher Education of the Republic of Kazakhstan (grants AP13067774 and BR24992761).

Competing interests. The authors declare that they have no competing interests.

Authors’ contribution. All authors made a substantial contribution to the conception of the work, acquisition, analysis, interpretation of data for the work, drafting and revising the work, final approval of the version to be published and agree to be accountable for all aspects of the work. The greatest contribution is distributed as follows: Kurmet G. Satenov – interpretation of data, writing and editing of the manuscript; Yerlan M. Suleimen – collection, analysis and inter-pretation of the data, checking the results and editing the manuscript; Zholaman A. Tashenov – the concept of the work, interpretation of the data and progress monitoring.

ДОПОЛНИТЕЛЬНО

Источник финансирования. Данное исследование финансируется Комитетом науки Министерства науки и высшего образования Республики Казахстан (гранты AP13067774 и BR24992761).

Конфликт интересов. Авторы декларируют отсутствие явных и потенциальных конфликтов интересов, связанных с публикацией настоящей статьи.

Вклад авторов. Все авторы подтверждают соответствие своего авторства международным критериям ICMJE (все авторы внесли существенный вклад в разработку концепции, проведение исследования и подготовку статьи, прочли и одобрили финальную версию перед публикацией). Наибольший вклад распределён следующим образом: Сатенов К.Г. – интерпретация данных, написание и редактирование рукописи; Сүлеймен Е.М. – сбор, анализ, интерпретация данных, проверка результатов, редактирование рукописи; Ташенов Ж.А. – концепция работы, интерпретация данных, контроль за выполнением работы.

 

1 On Approval of the General scheme of gasification of the Republic of Kazakhstan for 2023–2030. Order of the Minister of Energy of the Republic of Kazakhstan dated September 29. 2023. N 350.

2 On Approval of the General Scheme of Gasification of the Republic of Kazakhstan for 2023 – 2030. Order from the Minister of Energy of the Republic of Kazakhstan dated September 29. 2023. N 350.

3 Handbook of Best Available Techniques “Oil and Gas Production”. 5.9.2 Gas injection into the reservoir. Government deсree of the Republic of Kazakhstan dated December 27. 2023. N. 1202.

×

Авторлар туралы

Құрмет Ғ. Сатенов

ҚМГ Инжиниринг

Хат алмасуға жауапты Автор.
Email: K.Satenov@kmge.kz
ORCID iD: 0000-0002-6396-913X

канд. хим. наук

Қазақстан, Астана қаласы

Ерлан Мэлсұлы Сүлеймен

ҚМГ Инжиниринг; Қазақ технология және бизнес университеті

Email: Ye.Suleimen@kmge.kz
ORCID iD: 0000-0002-5959-4013

PhD

Қазақстан, Астана қаласы; Астана қаласы

Жоламан Ә. Тәшенов

ҚМГ Инжиниринг

Email: Zh.Tashenov@kmge.kz
ORCID iD: 0009-0005-6462-8600

PhD

Қазақстан, Астана қаласы

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2. Figure 1. General process flow diagram of the Gas Processing Plants CPC –Pipeline; DE – Design Engineering; COS – Carbonyl sulfide; RSH – Mercaptans

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3. Figure 2. Vessel type slug catcher [6]

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4. Figure 3. Finger type slugcatcher [7]

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5. Figure 4. Process flow diagram of gas production units with combined gas drying processes. NGL – Natural Gas Liquid

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6. Figure 5. Process flow diagram of gas production units with combined gas drying processes using molecular sieves

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7. Figure 6. General block diagram of gas injection process

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