Flare gas recovery systems have become increasingly important in oil and gas production facilities around the world. As concerns about carbon emissions and wasteful practices rise, recovering flare gas provides significant environmental and economic benefits. This article will provide an overview of flare gas recovery systems, their purpose and benefits, as well as the technologies involved.

What is Flare Gas?
Before discussing flare gas recovery systems, it's important to understand what flare gas is. Flare gas, also known as flare stack gas, is a mixture of hydrocarbon gases that are produced as a byproduct during oil and gas production operations. These gases, which include methane, ethane, propane and other heavier hydrocarbons, are normally burned or "flared" through an open flame at the production site. However, flaring releases greenhouse gases into the atmosphere and wastefully destroys potentially valuable hydrocarbon resources.

The Purpose of Flare Gas Recovery
The primary purpose of a flare gas recovery system is to capture hydrocarbon gases that would otherwise be flared and make productive use of them. By recovering flare gas, production facilities can reduce carbon emissions that contribute to climate change. The recovered gases can also be reintegrated into production processes, used as an on-site fuel source, or treated and exported for sale. This converts an environmental liability into a revenue stream. Flare gas recovery thus provides both sustainability and economic benefits compared to conventional flaring practices.

Components of a Flare Gas Recovery System
A typical flare Flare Gas Recovery Systems consists of several main components:

- Knockout Drums - Used to separate liquids, water and solids from the flare gas stream. This prepares the gas for further treatment.

- Compressors - Compress the recovered gases to higher pressures so they can be integrated into production or pipelined for transport. Different types may be used depending on throughput needs.

- Dehydration Units - Remove remaining water vapor from the gas to prevent hydrate formation and corrosion downstream. Often an amine or glycol dehydration system.

- Mercury Removal - If natural gas liquids are being recovered, mercury may need removal to meet pipeline specifications. Activated alumina or other sorbent beds can handle this.

- pipelines and Valves - Used to transport compressed recovered gas between major components and tie-in points. Control valves properly regulate flow.

- Flare Knockout Drums - Collect any final knockout of liquids before directing clean gas to its end use.

- Controls and Instrumentation - Monitor and control the recovery system automatically or with human supervision. Protect components and ensure steady operations.

Benefits of Recovering Flare Gas
The environmental and economic rewards of recovering flare gas make the investment in a recovery system very worthwhile:

- Greenhouse Gas Reduction - By far the largest benefit. Recovered methane has a global warming potential 25x that of CO2.

- Monetization of Formerly Wasted Resources - With treatment, the recovered hydrocarbons can be put to higher value uses like power generation, pipeline injection or LNG/LPG production.

- Revenue Generation - The sale of recovered gas componentsGenerates a new stream of income for production sites. Commonly offsetting 30-50% of the capital cost within 3 years according to the EPA.

- Regulatory Compliance - Many jurisdictions now restrict or outright ban continuous flaring. Proper recovery systems help satisfy these mandates.

- Improved Site Efficiency - Recovered gas can fuel pumps, turbines and more to decrease reliance on costly grid electricity or delivered fuels.

- Positive ESG and Community Image - Flare elimination projects garner goodwill for applying principles of sustainability and waste reduction. This aids in the social license to operate for oil/gas firms.

Technologies for Optimized Recovery
While basic flare gas recovery can approach 80% efficiency, advanced technologies are available to optimize system performance:

- Vapor Recovery Units (VRUs) - Sophisticated VRUs can efficiently separate volatiles from liquids streams with multiple separation steps down totrace levels.

- Membrane Separation - Gas selective membrane modules provide a very compact method to enrich methane content before further use or transport.

- Cryogenic Processing - For rich gas streams, this highly effective routechills feed to -160°C/-256°F to fractionate NGLs from natural gas.

- Digital Transformation - The latest "digital oilfield" advances apply automation, artificial intelligence and advanced controls for optimized operations around-the-clock.

- Flare Gas Hydrate Inhibition - Specialized antifreeze injection prevents hydrate blockages even at very high gas throughputs in arctic conditions.

In summary, flare gas recovery systems offer major economic and environmental returns by reducing waste and putting formerly flared hydrocarbon resources to higher value uses. As regulations tighten and producers aim for sustainability, recovery of what was once considered a byproduct is now best practice. Ongoing innovations will further maximize the benefits of eliminating continuous gas flaring at oil and gas facilities worldwide.

 

 

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