Artificial lift refers to the use of manual methods to increase the flow of liquid (eg, crude oil or water) from a production well. Typically, this is achieved by using a mechanical device (called a pump or velocity column) in the well or by injecting gas into the liquid at a distance down the well to reduce the weight of the still water column. A new method called continuous belt transport (CBT) uses oil absorbing belts to extract from edge and idle wells. Artificial lift is required in wells when the pressure in the reservoir is not sufficient to lift the produced fluid to the surface, but is often used in naturally flowing wells (technically not needed) to increase the flow rate above natural flow. Flow rate. The fluid produced can be oil, water or a mixture of oil and water, usually mixed with a quantity of gas.
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The natural decline in reservoir energy will affect the flow of oil, gas or water, resulting in instability and a drop in production. Artificial lifts are used for petroleum-based or liquid-loaded gas systems to increase and stabilize hydrocarbon production and minimize flow assurance and operational risks, such as slugs in subsea production systems. The artificial lifting method transfers energy to the generated fluid in order to reduce fluid density and head pressure or increase flow pressure. The three most commonly used artificial lifting methods in the seabed environment include: gas lift, subsea boost, electric submersible pump.
Any reservoir of fluid production creates “reservoir pressure”: a certain amount of energy or potential forces the fluid (liquid, gas, or both) into areas of lower energy or potential. This concept is similar to the water pressure in the municipal water supply system. Once the pressure in the production well is reduced below the reservoir pressure, the reservoir acts as a filling well, just like opening a valve on a water system. Depending on the depth of the reservoir and the density of the fluid, the reservoir may or may not have sufficient potential to push the fluid towards the surface – deeper wells or heavier mixtures result in higher pressure requirements.
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Under COVID-19 outbreak globally, this report provides 360 degrees of analysis from supply chain, import and export control to regional government policy and future influence on the industry. Detailed analysis about market status (2015-2020), enterprise competition pattern, advantages and disadvantages of enterprise products, industry development trends (2020-2025), regional industrial layout characteristics and macroeconomic policies, industrial policy has also been included. From raw materials to end users of this industry are analyzed scientifically, the trends of product circulation and sales channel will be presented as well. Considering COVID-19, this report provides comprehensive and in-depth analysis on how the epidemic push this industry transformation and reform.
In COVID-19 outbreak, Chapter 2.2 of this report provides an analysis of the impact of COVID-19 on the global economy and the Subsea Artificial Lift Systems industry.
Chapter 3.7 covers the analysis of the impact of COVID-19 from the perspective of the industry chain.
In addition, chapters 7-11 consider the impact of COVID-19 on the regional economy.
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The Subsea Artificial Lift Systems market can be split based on product types, major applications, and important countries as follows:
Key players in the global Subsea Artificial Lift Systems market covered in Chapter 12:
Baker Hughes
United Drilling Tools
JJ Tech
Epic Lift Systems
Multi-Chase Group
Flotek Industries
Dover Artificial Lift
National Oilwell Varco
Halliburton
Lycon
NOVOMET
Borets
Weatherford
Tenaris
Superior Energy Services
Schlumberger
General Electric
In Chapter 4 and 14.1, on the basis of types, the Subsea Artificial Lift Systems market from 2015 to 2025 is primarily split into:
Electric Submersible Pump System
Progressive Cavity Pump System
Rod Lift
In Chapter 5 and 14.2, on the basis of applications, the Subsea Artificial Lift Systems market from 2015 to 2025 covers:
Oil Wells
Gas Wells
Geographically, the detailed analysis of consumption, revenue, market share and growth rate, historic and forecast (2015-2025) of the following regions are covered in Chapter 6, 7, 8, 9, 10, 11, 14:
North America (Covered in Chapter 7 and 14)
United States
Canada
Mexico
Europe (Covered in Chapter 8 and 14)
Germany
UK
France
Italy
Spain
Russia
Others
Asia-Pacific (Covered in Chapter 9 and 14)
China
Japan
South Korea
Australia
India
Southeast Asia
Others
Middle East and Africa (Covered in Chapter 10 and 14)
Saudi Arabia
UAE
Egypt
Nigeria
South Africa
Others
South America (Covered in Chapter 11 and 14)
Brazil
Argentina
Columbia
Chile
Others
Years considered for this report:
Historical Years: 2015-2019
Base Year: 2019
Estimated Year: 2020
Forecast Period: 2020-2025
Table of Contents
1 Subsea Artificial Lift Systems Introduction and Market Overview
1.1 Objectives of the Study
1.2 Overview of Subsea Artificial Lift Systems
1.3 Scope of The Study
1.3.1 Key Market Segments
1.3.2 Players Covered
1.3.3 COVID-19’s impact on the Subsea Artificial Lift Systems industry
1.4 Methodology of The Study
1.5 Research Data Source
2 Executive Summary
2.1 Market Overview
2.1.1 Global Subsea Artificial Lift Systems Market Size, 2015 – 2020
2.1.2 Global Subsea Artificial Lift Systems Market Size by Type, 2015 – 2020
2.1.3 Global Subsea Artificial Lift Systems Market Size by Application, 2015 – 2020
2.1.4 Global Subsea Artificial Lift Systems Market Size by Region, 2015 – 2025
2.2 Business Environment Analysis
2.2.1 Global COVID-19 Status and Economic Overview
2.2.2 Influence of COVID-19 Outbreak on Subsea Artificial Lift Systems Industry Development
….CONTINUED