Industries and Applications
We Serve
Early production facilities (EPF)
Early Production Facilities (EPF) are temporary or modular installations designed to enable the rapid startup of oil and gas production from newly drilled wells. These facilities allow operators to process and separate crude oil, gas, and water at the well site before permanent production infrastructure is completed. EPFs typically include essential equipment for initial fluid separation, storage, and measurement, enabling early cash flow and reservoir data collection while full-scale surface production facilities are being constructed. Their flexible and scalable design makes them a practical solution for accelerating field development and optimizing project economics
Gas processing
Gas processing plays a critical role in the upstream sector of the oil and gas industry. After extraction at the wellhead, raw natural gas often contains impurities such as water vapor, hydrogen sulfide, carbon dioxide, and natural gas liquids (NGLs). Gas processing facilities are responsible for removing these contaminants and separating valuable byproducts to ensure the gas meets the quality specifications required for pipeline transmission or commercial use. By efficiently treating and conditioning the gas at or near the production site, gas processing enhances the value chain, supports safe and reliable transportation, and contributes to the overall profitability and operational efficiency of upstream operations
Surface Production Facilities
Surface Production Facilities are a vital component of the upstream oil and gas sector. These facilities encompass all the infrastructure and equipment located above ground that are necessary for the processing, separation, treatment, storage, and measurement of hydrocarbons produced from oil and gas wells. In the upstream phase, after hydrocarbons are extracted from underground reservoirs, they are brought to the surface where surface production facilities handle the initial stages of production. This typically includes separating oil, gas, and water; removing impurities; and preparing the products for further processing, storage, or transportation.​
The design and operation of surface production facilities are tailored to the specific characteristics of the reservoir and production strategy. They may include wellhead compression units to boost pressure, early production facilities (EPF) for rapid project startup, and gas processing plants to ensure that natural gas meets required quality standards for pipeline transmission or commercial sale. By efficiently managing these critical processes at or near the production site, surface production facilities help maximize resource recovery, accelerate cash flow, and ensure the safety and reliability of upstream operations
CNG compression
CNG Compression refers to the process of compressing natural gas to a high pressure, typically between 3,000 and 3,600 psi, to convert it into Compressed Natural Gas (CNG) for efficient storage and transportation. In the context of oil and gas upstream operations, CNG compression is utilized to manage associated or produced natural gas at the well site, especially in remote or early-stage developments where pipeline infrastructure may not yet be available. By compressing natural gas, operators can capture and monetize gas that might otherwise be flared or vented, thereby reducing emissions and enhancing project economics.
CNG compression also enables flexible gas handling solutions, allowing for safe transport by trailer or other means to downstream processing facilities or end users. Incorporating CNG compression into upstream operations supports environmental compliance, maximizes resource utilization, and provides an interim solution until permanent gas processing or pipeline infrastructure is established.
Virtual pipeline
Virtual pipeline refers to a logistics solution used in the upstream oil and gas sector to transport compressed natural gas (CNG) or liquefied natural gas (LNG) from production sites to end users or processing facilities without relying on traditional, fixed pipeline infrastructure. Instead, natural gas is compressed or liquefied at the well site and loaded onto specially designed trailers, trucks, rail cars, or barges for overland or waterborne transport.
This approach is particularly valuable in remote or early-stage field developments where permanent pipelines are not yet available or economically viable. By utilizing virtual pipelines, operators can monetize stranded or associated gas that might otherwise be flared or vented, thereby reducing emissions and enhancing project economics. Virtual pipelines also offer flexibility and scalability, allowing for the safe and efficient delivery of natural gas to a variety of markets, including power generation facilities, industrial plants, or local distribution networks. This solution supports environmental compliance, maximizes resource utilization, and serves as an interim or long-term alternative to traditional pipelines, especially in regions facing regulatory, logistical, or geographical challenges.
In summary, virtual pipelines bridge the gap between upstream production and downstream demand in situations where conventional pipelines are impractical, ensuring that valuable natural gas resources are efficiently captured, transported, and utilized.
Pipeline evacuation
Pipeline evacuation is a critical process in upstream oil and gas operations, involving the safe and efficient removal of hydrocarbons, water, or other fluids from pipelines. This practice is essential during maintenance, commissioning, decommissioning, or emergency situations to ensure the integrity and safety of pipeline infrastructure. In the context of early field development, pipeline evacuation enables operators to clear lines prior to startup or after temporary production phases, minimizing risks of contamination, corrosion, or environmental incidents. Advanced evacuation techniques may include the use of inert gases, pigs, or specialized pumps to thoroughly purge pipelines, thereby supporting operational reliability and regulatory compliance.
By effectively managing pipeline evacuation, upstream projects can optimize fluid handling, reduce downtime, and uphold high standards for environmental protection and workplace safety.
Pipeline transmission
Pipeline Transmission is a fundamental aspect of the oil and gas upstream sector, serving as the primary method for transporting processed hydrocarbons—such as natural gas, crude oil, or their derivatives—from production sites to processing plants, storage facilities, or downstream users. After gas has undergone necessary treatment and conditioning at surface production facilities or gas processing plants, pipeline transmission ensures the safe, reliable, and cost-effective movement of these products over long distances.Modern pipeline systems are engineered to operate under high pressure and are constructed from durable materials to withstand a range of environmental and operational challenges.
The design and operational protocols for pipeline transmission take into account the specific properties of the hydrocarbons being transported, as well as factors such as terrain, climate, and regulatory requirements. Advanced monitoring and control systems are often integrated to detect leaks, manage flow rates, and maintain pipeline integrity, thereby minimizing environmental risks and supporting operational safety.Within the context of upstream operations, efficient pipeline transmission enables operators to minimize flaring or venting by providing a continuous and controlled route for hydrocarbon evacuation.
This not only supports environmental compliance and resource conservation but also maximizes economic returns by ensuring timely delivery of products to market. Additionally, the ability to rapidly evacuate or commission pipelines during maintenance or early production phases is critical for project flexibility and risk management.
Overall, pipeline transmission acts as a vital link in the oil and gas value chain, facilitating the seamless integration of upstream production with midstream and downstream activities while upholding high standards for safety, reliability, and environmental stewardship.
Gas gathering
Gas gathering is a critical component in upstream oil and gas operations, involving the collection and consolidation of natural gas from multiple wells or production sites. This process typically utilizes a network of small-diameter pipelines—known as gathering lines—that transport raw natural gas, often containing impurities and liquids, from individual wellheads to central processing facilities or compressor stations. In early field developments or remote locations where extensive infrastructure may not yet exist, gas gathering systems provide a flexible and scalable solution to efficiently manage and monetize produced gas.
Implementing an effective gas gathering system allows operators to capture associated or produced gas that might otherwise be flared or vented, thereby reducing greenhouse gas emissions and supporting regulatory compliance. By aggregating gas from dispersed sources, gathering systems optimize resource utilization, enable economies of scale, and facilitate the delivery of gas to downstream markets or processing plants. Advanced systems may integrate metering, flow control, and real-time monitoring to enhance operational reliability, detect leaks quickly, and maintain safety throughout the gathering network. In summary, gas gathering serves as a vital link between wellsite production and downstream processing or transmission, enabling operators to maximize the value of their natural gas resources while upholding high standards for environmental stewardship and operational efficiency
Wellhead compression
Wellhead compression plays a pivotal role in upstream oil and gas operations, particularly in fields where reservoir pressure is insufficient to drive produced gas through pipelines or gathering systems. By installing compressors directly at or near the wellhead, operators can boost the pressure of natural gas, enabling its efficient transportation to central processing facilities, gathering networks, or transmission pipelines. This technique is especially valuable in mature fields, low-pressure reservoirs, or early field developments where maintaining steady production flow is critical.
The implementation of wellhead compression helps prevent the loss of recoverable hydrocarbons by reducing the need for flaring or venting and supports regulatory compliance by minimizing emissions. Advanced compressor units are often equipped with automated controls, safety shutdowns, and real-time monitoring systems to optimize
performance, ensure operational safety, and quickly detect any issues. In addition, modular and scalable compressor designs allow for flexible deployment, adapting to changing reservoir conditions and production rates.
Overall, wellhead compression enhances resource recovery, maximizes economic returns, and strengthens the reliability of upstream operations. By ensuring consistent gas flow from wells with declining pressures, it serves as a strategic solution for extending the productive life of assets and supporting the seamless integration of wellsite production with downstream gathering, processing, and transmission infrastructure
Power generation
Power generation is an essential aspect of upstream oil and gas operations, providing the reliable energy needed to run critical equipment and processes at wellsites, production facilities, and remote field locations. In many upstream environments, especially those situated far from established power grids, operators rely on on-site power generation systems—such as gas turbines, reciprocating engines, or small-scale generators—to supply electricity for drilling rigs, pumps, compressors, monitoring systems, and safety infrastructure.Integrating power generation directly with upstream activities offers several strategic advantages.
By utilizing produced gas—either associated or non-associated—as a fuel source, operators can reduce flaring and venting, optimize resource utilization, and enhance environmental performance. This approach not only supports regulatory compliance by minimizing emissions but also transforms what might otherwise be a waste product into a valuable energy resource, improving project economics and sustainability.
Advanced power generation solutions in upstream settings often include modular, scalable systems designed to adapt to fluctuating field demands and changing production rates. These systems may feature automated controls, remote monitoring, and integrated safety mechanisms to ensure efficient, reliable, and safe operation. In addition, the ability to rapidly deploy or relocate power generation assets supports project flexibility, enabling operators to respond quickly to new developments, maintenance needs, or expansion opportunities.
Overall, power generation acts as a critical enabler for upstream oil and gas operations, facilitating continuous production, supporting essential infrastructure, and contributing to the seamless integration of wellsite activities with downstream processing and transmission networks. Its role in harnessing produced gas for energy further underscores its value in promoting operational efficiency, environmental stewardship, and long-term asset performance.
Flare reduction
Flare reduction is a key objective in upstream oil and gas operations, focusing on minimizing the controlled burning of excess natural gas at wellsites and production facilities. By implementing advanced technologies and operational strategies, operators can significantly decrease flaring activities, thereby reducing greenhouse gas emissions, conserving valuable hydrocarbons, and enhancing environmental stewardship.One effective approach to flare reduction involves capturing and utilizing produced gas that would otherwise be flared. This can be achieved by integrating wellhead compression and on-site power generation systems, which enable the efficient transport and conversion of natural gas into electricity for field operations.
Not only does this optimize resource utilization, but it also transforms waste gas into a valuable energy source, supporting sustainability and regulatory compliance.
Modern flare reduction initiatives often leverage real-time monitoring, automated controls, and modular equipment to adapt to changing production rates and reservoir conditions. These solutions ensure consistent performance, enhance operational safety, and provide flexible deployment options to meet evolving field requirements. By prioritizing flare reduction, operators contribute to improved air quality, lower carbon footprints, and greater overall efficiency in upstream oil and gas activities.
Ultimately, flare reduction supports the seamless integration of wellsite production with downstream processing and transmission networks, while promoting responsible resource management and long-term asset performance.
Vapor recovery
Vapor recovery is a crucial process in upstream oil and gas operations, aimed at capturing hydrocarbon vapors that would otherwise be released into the atmosphere during production, storage, or transfer activities. By deploying vapor recovery units (VRUs) at wellsites and production facilities, operators can efficiently collect volatile organic compounds (VOCs) and natural gas liquids (NGLs) from storage tanks, separators, and other equipment.
These recovered vapors are then compressed and either reinjected into the production system, used as a fuel source for on-site power generation, or sent to sales pipelines—transforming potential emissions into valuable resources. The implementation of vapor recovery systems delivers multiple benefits: it reduces greenhouse gas and VOC emissions, mitigates regulatory risks, and enhances environmental compliance. Additionally, by capturing and monetizing hydrocarbon vapors, operators can improve operational efficiency and project economics. Modern VRUs often feature automated controls, real-time monitoring, and modular designs, enabling rapid deployment and adaptability to fluctuating production rates and field conditions.
Incorporating vapor recovery into upstream operations also supports broader sustainability goals. By minimizing emissions and maximizing hydrocarbon utilization, vapor recovery contributes to responsible resource management and strengthens the integration of wellsite activities with downstream processing and transmission networks. This approach not only aligns with evolving environmental regulations but also reinforces the industry's commitment to operational excellence and long-term asset performance.