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Advances in Gas Treatment Technologies Enable More Efficient Operations
Gas treatment refers to the processes used to remove unwanted components such as water, carbon dioxide, hydrogen sulfide, and mercury from natural gas and produced hydrocarbon gases. Treatment is necessary to meet the quality specifications for sale and transportation of gas and its by-products. It also prevents corrosion and handling issues downstream. Some key gas treatment processes include dehydration, sweetening, and mercury removal.
Gas Dehydration
One of the primary processes in it is dehydration which removes water vapor from the raw gas. The presence of water can cause serious operational issues like hydrate formation and corrosion. There are two main dehydration methods — glycol dehydration and molecular sieve dehydration. Glycol dehydration uses a glycol such as triethylene glycol (TEG) to absorb water from the gas. The glycol gets regenerated by distillation. Molecular sieve dehydration uses zeolite beds that adsorb water molecules from the gas onto their internal surface due to differences in molecular size. Heat regeneration releases the water. Molecular sieve dehydration is more energy-efficient and results in extremely low water content, down to 1 ppmv.
Gas Sweetening
Another critical gas treatment process is sweetening which removes hydrogen sulfide (H2S) — a toxic, corrosive, and odorous substance. The common sweetening methods are amines treatment and LO-CAT sweetening. In amine treatment, an aqueous amine solution like monoethyleneamine (MEA) chemically absorbs H2S from the acid gas stream. The sulfiderich amine is regenerated using heat. LO-CAT or Low-Temperature Carbon Adsorption Treatment uses a proprietary activated carbon which adsorbs H2S molecules onto its surface at relatively low temperatures. The sweetening process enables monetization of sour gas by converting it into salable pipeline-quality dry natural gas.
Mercury Removal
Mercury is another problematic substance that needs to be removed from gas streams. Left untreated, it can cause serious operational issues as liquid metallic mercury in pipelines and equipment. Activated carbon adsorption is commonly used for mercury removal. First, oxidized mercury is converted to elemental mercury which then gets adsorbed onto the surface of carbon granules. Periodic replacement/regeneration of loaded carbon beds is done to maintain high mercury removal efficiency. Newer solid sorbent technologies are also gaining ground due to their ability to remove elemental and oxidized mercury forms.
Gas Processing Plants
The key facilities for gas treatment are centralized gas processing plants that cater to multiple upstream natural gas production assets like wells and flowlines. They handle large volumes of raw produced gas. A typical grassroots gas plant setup involves several dehydration, sweetening and mercury removal units operating in a series configuration. Various separators, tanks, compressors and utilities are also part of the integrated system. Automated control systems ensure smooth functioning of plant operations 24/7. Periodic maintenance helps sustain high performance in corrosive sour gas environments.
Gas Specifications
It is important for gas from treatment facilities to meet the quality specifications set by pipeline transmission companies and LNG terminals. The specifications commonly include parameters like water dew point, hydrocarbon dew point, hydrogen sulfide and total sulfur content, overall heating value, and mercury content. Compliance is necessary for interstate/country transportation and monetization of sales gas. Upset conditions in remote gas fields may require portable or skid-mounted units as pre-treatment to help meet
Gas to Liquids Conversion
It also enables further conversion of raw gas into valuable liquefied natural gas (LNG) and gas-to-liquids (GTL) products using advanced processes. For the LNG process, multi-stage refrigeration is used to condense treated gas into liquid form at -162°C for safe marine transportation. Key gas specifications like water, H2S and mercury levels need to be closely controlled. Similarly, syngas production and Fischer-Tropsch synthesis in GTL plants use sweetened gas as feedstock to produce cleaner burning synthetic fuels and chemicals. Thus, thorough it forms an indispensable initial step in the monetization of remote resources.
Environmental Regulations
Stringent environmental regulations also drive advancements in it. Regulations limit the amount of contaminants like sulfur that can be emitted during flaring and incineration of acid gases. This necessitates high sulfide removal efficiencies. Similarly, concerns over air toxins have increased focus on mercury capture. Operators closely monitor emissions to remain compliant and prevent penalties. Ongoing R&D aims to develop more cost-effective and ecofriendly treatment solutions through innovations in materials, designs and process revamps. Related services around emissions monitoring and reporting further enable regulatory compliance.
gas treatment plays a vital role in the oil and gas industry by enabling monetization and transport of hydrocarbons from production fields to applications and endusers worldwide. It overcomes problems associated with impurities and opens doors for further downstream conversions. Advancements are ongoing to achieve higher efficiencies while reducing costs and environmental footprint. Gas treatment will continue to see new technologies and become central to industry operations in the future.
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