Technical, Economic and Environmental Considerations for Selecting Next Generation Hydraulic Fracturing Equipment Technology

Fu, Dan; Zemlak, Warren; Yeung, Tony; Barclay, Caleb; Gorchynski, Trevor

doi:10.2118/210215-ms

SPE Annual Technical Conference and Exhibition 2022

DOI: 10.2118/210215-ms

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Technical, Economic and Environmental Considerations for Selecting Next Generation Hydraulic Fracturing Equipment Technology

Dan Fu¹,

Warren Zemlak²,

Tony Yeung³

et al.

Abstract: Recently, the North America Oil and Gas industry has seen a rapid increase in the adoption of new hydraulic fracturing technologies such as dual-fuel diesel engine, electric system powered by gas turbine or engine on-site and turbine direct drive technology, to reduce emissions and operating costs. The objective of this paper is to provide a detailed analysis of economic, environmental, and technical considerations when selecting the next generation hydraulic fracturing equipment platform. It is… Show more

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Natural Gas Powered Direct-Drive Turbine Hydraulic Fracturing Technology Delivers High Power Density and Energy Transfer Efficiency for Environmental, Economic and Operational Benefits

Rodriguez¹,

Rodriguez²,

Barron³

et al. 2023

Day 2 Thu, March 16, 2023

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In today's hydraulic fracturing operations there is an increasing demand for more rate and pressure resulting in more energy intense operations. Therefore, there is a need for more horsepower (HP) to be available on site. In order to support this, along with the industry's transition into a sustainable and low carbon footprint initiative, companies have devoted great efforts in research and development into developing the next generation hydraulic fracturing equipment. As a result, the first natural gas powered 5,000 HP direct drive turbine fracturing pumper has recently been introduced in North America. The objective of this paper is to provide technical insights on how the direct drive gas turbine technology brings a high-power density and efficient energy transfer solution to deliver operational, economic, and environmental benefits. The industry had limited success in utilization of the direct drive gas turbine technology in the past. The main obstacles were unreliable and inefficient turbine to pump power transfer mechanism, low power density, and lack of an integrated engineering approach. The advancements in gas turbines and speed reduction technology, coupled with an in-depth application of equipment design knowledge allowed the company to successfully develop the next generation of hydraulic fracturing technology. The technology is a power train consisting of a 5,000 HP gas turbine engine (5,336 HP actual), a robust single stage reduction gearbox, and a 5,000 HP continuous duty pump. The direct drive turbine technology brings one of the highest power densities and efficient mechanical power transfer designs on the market today. The technology utilizes a split shaft gas turbine to allow for a power gapless powertrain, linear output rpm, and low speed high torque capabilities. A wide variety of fuels can be used including compressed natural gas (CNG), liquefied natural gas (LNG), field gas, and liquid fuel (e.g., diesel). Based on certified third-party emissions data, the direct drive technology is shown to have one of the lowest greenhouse gases (GHG) and Environmental Protection Agnecy (EPA) regulated emissions profiles. At the time of this writing, the first direct drive turbine frac fleet has been deployed in the Haynesville for 2 years and more recently introduced in Canada (Montney and Duvernay).

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Natural Gas Powered Direct-Drive Turbine Hydraulic Fracturing Technology Delivers High Power Density and Energy Transfer Efficiency for Environmental, Economic and Operational Benefits

Rodriguez¹,

Rodriguez²,

Barron³

et al. 2023

Day 2 Thu, March 16, 2023

View full text Add to dashboard Cite

show abstract

Digitization of Hydraulic Fracturing Operations Enables GHG Emissions Reduction, Operational Efficiency, and Reliability

Barron¹,

Rodriguez²,

Rodriguez³

et al. 2023

Day 2 Thu, March 16, 2023

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As the job intensity increases, in the form of flow rate and pressure, there is a continuous need for increased amount of horsepower for hydraulic fracturing operations. Nevertheless, increasing the number of units at the wellsite to achieve this demand in horsepower is an impractical solution when attempting to reduce carbon footprint. Instead, increasing the power density, energy transfer efficiency, and reducing the amount of parasitic loss offers a superior solution with the introduction of the first natural gas-powered 5,000 HP direct-drive turbine fracturing pumps in North America. A methodology was developed to select this direct-drive turbine technology as the next-generation hydraulic fracturing equipment. The direct-drive pumping unit is equipped with a 5,000 hp continuous duty power end driven by a 5,000 hp dual shaft turbine through a single speed reduction gearbox. This combination provides the most efficient mechanical power transfer efficiency resulting in significant fuel cost savings and reduction in greenhouse gas emissions. In conjunction, a new digital control system has been developed and deployed to enable operational automated functionalities for the pumping unit and backside equipment. This innovative control system provides open interoperable controls, and data analytics for the purpose of eliminating uninformed decisions from pump operators as well as predicting and preventing equipment failures. The objective of this paper is to provide technical details on how digitization enables operational efficiency, equipment reliability, and emission reduction for the direct drive turbine technology.

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A Comprehensive Life Cycle Assessment of Hydraulic Fracturing

Khan,

Anderson,

Prabhu

et al. 2024

SPE International Health, Safety, Environment and Sustainability Conference and Exhibition

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The oil and gas industry has been taking steps to achieve sustainable growth. Most E&P companies have declared their commitment to a carbon-neutral future. The first step in realizing this goal is to identify high-intensity operations, such as unconventional hydraulic fracturing and reduce those emissions. Therefore, the primary objective of this work is to quantify the main sources of emissions in the hydraulic fracturing value chain and identify technologies that could drastically reduce those emissions. The main purpose of this work is to identify nearly all sources of emissions and the scale of their impact. Once the main emission sources are identified in the entire unconventional fracturing chain, we then focus on technologies that enable significant emission reduction. We employed qualitative and quantitative analysis to assess the emissions impact of diesel engines, material transportation, and water utilization. Our observations yielded a high-level view of emission intensity across the value chain of hydraulic fracturing. Wellsite execution related fuel consumption during pumping was the highest contributor to emissions at 36%, followed closely by the flaring for fracture cleanup at 29%. Total transportation contributed 24% to the total emissions. While the emissions of the fracturing fleets are often very visible due to their large footprint and duration, surprisingly, the nonroutine flaring and transportation are also impactful. In fact, nonroutine flaring could have much higher impact depending on how fast the cleanup process could take place, which may not be easy to predict. It is reported that using natural gas in internal combustion engines reduced the CO2 emissions. However, the methane leak from engines would offset the CO2 savings and render the benefits marginal. We also observed that the reuse of produced water to be a feasible way to reduce the well stimulation footprint on water resources, which could be enabled by improved water treatment techniques at scale, advances in hydraulic fracturing fluid composition, and appropriate infrastructure. We quantified the upstream emissions (embodied carbon) of commonly used chemicals. Our calculations show that the embodied carbon of commonly used chemicals in unconventional fracturing is rather small. Our conclusions emphasize the importance of adopting ecofriendly technologies to address the challenges posed by hydraulic fracturing. They can impact up to 35% of emissions reduction. This study contributes a high-level, yet accurate, perspective on emissions of the hydraulic fracturing process. We highlight the high-emitting steps in the process and identify technology gaps that could reduce the emission footprint of the industry. This research underscores the urgency of adopting responsible practices in hydraulic fracturing for a harmonious coexistence with global sustainability objectives.

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Technical, Economic and Environmental Considerations for Selecting Next Generation Hydraulic Fracturing Equipment Technology

Cited by 3 publications

References 0 publications

Natural Gas Powered Direct-Drive Turbine Hydraulic Fracturing Technology Delivers High Power Density and Energy Transfer Efficiency for Environmental, Economic and Operational Benefits

Natural Gas Powered Direct-Drive Turbine Hydraulic Fracturing Technology Delivers High Power Density and Energy Transfer Efficiency for Environmental, Economic and Operational Benefits

Digitization of Hydraulic Fracturing Operations Enables GHG Emissions Reduction, Operational Efficiency, and Reliability

A Comprehensive Life Cycle Assessment of Hydraulic Fracturing

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