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石油・ガス産業における積層造形 (AM) 市場:2018-2029年

The Market for Additive Manufacturing in the Oil and Gas Sector 2018-2029

発行 SmarTech Analysis 商品コード 863489
出版日 ページ情報 英文 150 Pages
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石油・ガス産業における積層造形 (AM) 市場:2018-2029年 The Market for Additive Manufacturing in the Oil and Gas Sector 2018-2029
出版日: 2019年05月31日 ページ情報: 英文 150 Pages
概要

当レポートでは、石油・ガス産業における積層造形 (AM) 市場について調査し、全体的な市場機会の評価、主要な技術・材料の分析、および主要なサービスプロバイダーのプロファイルなど、体系的な情報を提供しています。

第1章 石油・ガス産業における積層造形 (AM) 技術の導入に関する機会の進化

  • AMの導入に影響する石油・ガス産業独自のダイナミクス
  • 石油・ガス産業の展望およびそのAM向けCapEx投資への反映
  • 石油・ガス産業における関連の導入セグメント
  • 石油・ガス産業向けAM技術
  • 石油・ガス産業向けAMの主なメリット
  • 石油・ガス産業向けの導入モデル
  • 石油・ガス産業向けAMの全体的な市場機会:10ヵ年予測
  • 予測手法
  • 本章の要点

第2章 石油・ガス産業におけるイノベーションを促進するAM技術・材料の分析

  • 石油・ガス産業によるAMハードウェア導入の概要
  • 石油・ガスで使用される金属AM技術の最新の発展
  • 石油・ガスで使用されるポリマー・複合材料向けAM技術
  • 石油・ガス産業向けAMに使用される材料の概要
  • 石油・ガス向けAMの金属材料
  • 石油・ガス向けAMのポリマー・複合材料
  • 石油・ガス向けAMにおけるセラミックス材料の大きな・依然として大きな未開発の可能性
  • 本章の要点

第3章 AM部品を用いた石油・ガス産業への貢献

  • 代表的な石油・ガス向けAM部品の分析
  • AM製品・プロセスライフサイクルの概要
  • AMにおける設計最適化の役割
  • 石油・ガスにおけるAM部品の需要
  • 石油・ガス産業における3Dプリント部品:10ヵ年予測
  • 本章の要点

第4章 石油・ガスサプライチェーンにおけるOEC企業・AMサービスのプロファイル

  • AMにおける近年の活動:OEC企業
  • AMにおける近年の活動:主要な石油・ガス産業サプライヤー・ステークホルダー
  • 石油・ガス産業におけるAMサービス収益の予測
  • 本章の要点
目次
Product Code: SMP-AM-OG-0519

Additive manufacturing (AM) in the oil and gas industry could have an impact unparalleled by any other industrial sectors based on complex engineering. However, only until very recently have the capabilities of additive manufacturing systems evolved to meet the oil and industry's stringent demands in terms of reliability, productivity and size capabilities. This report builds on SmarTech Analysis ongoing research into the oil and gas sector to accurately quantify the revenue opportunity and assesses the levels AM adoption in this field, based on AM hardware, materials services and parts produced through 2029. These include short- medium- and long terms opportunities for the upstream, midstream and downstream oil and gas industry segments.

This report covers the established areas of AM in oil and gas focusing primarily on current adoption of metal AM technologies such as metal powder bed fusion (PBF) and directed energy deposition (DED) including Wire Arc Additive Manufacturing (WAAM) processes. These technologies are analyzed in depth, along with material demand for all supported metal alloys (today and in the future) and part production capabilities with a particular focus on the more short-term opportunity presented by on-demand spare parts.

Based on SmarTech Analysis' unique and profound understanding of available AM technologies, materials and applications, the report then goes on to assess the overall oil and gas AM opportunity, including upcoming metal, polymer, composite and ceramic AM processes and materials that are going to gain wider adoption in the oil and gas industry during the 10-year forecast period examined. These include leading polymer technologies for prototyping, modeling, casting and final parts, as well as high-throughput metal AM technologies such as new bound metal/binder jetting and supersonic acceleration/cold blown powder processes.

We also profile some of the leading oil and gas AM service providers, highlighting unique trends in the oil and gas market that see specialized and trusted tier 1 and tier 2 (and tier 3) suppliers (including some AM service providers) become the primary adopters of AM to provide services to the largest oil companies. Within this scenario, SmarTech Analysis expects widespread AM adoption in the oil and gas industry to be driven by hardware sales rather than by AM service providers as in other industrial segments.

For each AM segment (hardware, materials, parts and services) , the ten-year forecasts contained in this report further break out the market by specific hardware technology, material type and support (metal and polymer powders, polymer and composite filaments and pellets, photopolymer resins and metal wire) , part types (prototypes, tools, replacement parts and mass produced final parts) and service type (tier 1, tier 2 suppliers) . Both revenue ($ Millions) and volume (units or kilograms/tonnes shipped) are considered in the forecasts.

Table of Contents

Chapter One: Evolution of the Opportunities for Adoption of Additive Manufacturing Technology in the Oil and Gas Industry

  • 1.1. Unique Oil and Gas Industry Dynamics Affecting Adoption of AM
    • 1.1.1. Opportunities for AM to Enter the Oil and Gas Supply Chain
    • 1.1.2. The Need to Ensure Reliability of Oil and Gas Parts and AM Processes
  • 1.2. Outlook for the Oil and Gas Industry in 2019 and How it Reflects on CapEx Investments for AM
    • 1.2.1. Oil and Gas Companies Are Ready to Spend
    • 1.2.2. Keeping the Supply Chain Optimized with New Technologies
    • 1.2.3. Decarbonization and Digitalization
    • 1.2.4. Pressure on the Supply Chain
  • 1.3. Relevant Adopting Segment in the Oil and Gas Industry
  • 1.4. Additive Manufacturing Technologies for the Oil and Gas Industry
  • 1.5. Key Benefits of AM for Oil and Gas
  • 1.6. Adoption Model for AM in Oil and Gas
  • 1.7. Ten-year Forecast of Overall Market Opportunity for AM in Oil and Gas
  • 1.8. Forecast Methodology
  • 1.9. Key Points from This Chapter

Chapter Two: Analyzing the AM Technologies and Materials Driving Innovation in the Oil and Gas Industry

  • 2.1. Overview of AM Hardware Adoption by the Oil and Gas Industry
    • 2.1.1. AM Technologies for the Oil and Gas Industry Considered in This Report
      • 2.1.1.1. Other AM Technologies That Could Become Relevant Long Term
      • 2.1.2.2. Tool-less manufacturing
    • 2.1.3. Ten-year Forecast for All AM Hardware in Oil and Gas
  • 2.2. Latest Evolutions of Metal AM Technologies Used in Oil and Gas
    • 2.2.1. Latest Evolutionary Trends in Metal AM Hardware Technologies for Oil and Gas Applications
      • 2.2.1.1. Powder Bed Fusion Retains Leadership
      • 2.2.1.2. Fast Growth of DED for Large Format Applications
      • 2.2.1.3. Will New Metal Binder Jetting Technologies Prove to Be Fit for Production Applications in Oil and Gas?
    • 2.2.2. Transitional AM Technologies
      • 2.2.2.1. Bound metal filament deposition desktop systems emerging as a viable studio prototyping solution for metal devices
      • 2.2.2.2. Sand-based binder jetting for casting
      • 2.2.2.3. Tracking the Emergence of Supersonic Consolidation Processes
    • 2.2.3. Ten-year Forecast for Metal AM Hardware in Oil and Gas
      • 2.2.3.1. Ten-year Forecast for Metal AM Hardware in Oil and Gas
  • 2.3. Polymer and Composite AM Technologies Used in Oil and Gas
    • 2.3.1. Latest Evolutionary Trends in Polymer AM Hardware Technologies for Oil and Gas Applications
      • 2.3.1.1. Polymer Powder Bed Fusion Could Become the Largest Hardware Opportunity Through Material Development
      • 2.3.1.2. Photopolymerization Evolves in Three Directions: Layerless, Industrial (+Casting) and Desktop Prototyping
      • 2.3.1.3. Different Applications for Pellet- and Filament-based Material Extrusion Technologies
    • 2.3.2. Ten-year Forecast for Polymer AM Hardware in Oil and Gas
  • 2.4. Overview of Materials Used for AM in the Oil and Gas Industry
    • 2.4.1. Material Development to Enable Additive Manufacturing in Oil and Gas
    • 2.4.2. Ten-year Forecast for All Materials in Oil and Gas AM
  • 2.5. Metal Materials for Oil and Gas AM
    • 2.5.1. Steel and Steel Alloys
    • 2.5.2. Nickel Alloys
    • 2.5.3. Cobalt Chromium
    • 2.5.4. Titanium
    • 2.5.5. Other Metals (Refractories, Tungsten Carbide, Tantalum, Molybdenum, Niobium)
    • 2.5.6. Ten-year Forecast for All Metal Materials in Oil and Gas AM
    • 2.5.7. Nickel Superalloys Emerging as Key Materials in Oil and Gas AM
    • 2.5.8. High Titanium Demand for Wire DED Processes in Oil and Gas Applications
      • 2.5.8.1. Ten-year Forecast of DED Materials in Oil and Gas
    • 2.5.9. Will Steels Reach Mass Productivity with Binder Jetting Technology?
      • 2.5.9.1. Ten-year Forecast of Binder Jetting Materials in Oil and Gas
    • 2.5.10. The Unique Case of Copper's Ultra-low Price in Supersonic Consolidation / Cold Blown Powder Processes
      • 2.5.10.1. Ten-year Forecast of Blown Metal Powder Materials in Oil and Gas
  • 2.6. Polymer and Composite Materials for Oil and Gas AM
    • 2.6.1. Key Polymer Material Suppliers for Oil and Gas Applications
    • 2.6.2. Ten-year Forecast for All Polymer Materials in Oil and Gas AM
    • 2.6.3. Trends for Metal Replacement Materials in Filament Extrusion Technologies
      • 2.6.3.1. Ten-year Forecast of Thermoplastic Filaments for Oil and Gas AM Applications
    • 2.6.4. Large-scale Oil and Gas Applications Now Accessible via Composite Pellet Extrusion
      • 2.6.4.1. Ten-year Forecast for Composite Pellet in Material Extrusion for Oil and Gas Applications
    • 2.6.5. Four Opportunities for Photopolymers in Oil and Gas AM
      • 2.6.5.1. Ten-year Forecast of Resin Materials for Photopolymerization Processes in Oil and Gas
    • 2.6.6. Advanced Materials for Polymer Powder Bed Fusion Could Open Doors to Higher Productivity of Oil and Gas Parts
      • 2.6.6.1. Ten-year Forecast of Thermoplastic Powder Materials in Oil and Gas
  • 2.7. The Large and Still Largely Unexploited Potential of Ceramic Materials in Oil and Gas AM
    • 2.7.1. Ceramics AM Technologies Fit for Oil and Gas Adoption
    • 2.7.2. Direct Production and 3D-printed Casts
    • 2.7.3. Advanced Ceramics for Oil and Gas Applications
      • 2.7.3.1. Ten-year Forecast of Ceramic Materials in Oil and Gas
  • 2.8. Key Points from This Chapter

Chapter Three: Servicing the Oil and Gas Industry with AM Parts

  • 3.1. Analysis of Typical AM Parts for Oil and Gas
    • 3.1.1. Advanced Prototyping and Modelling
    • 3.1.2. Molds, Cast Patters, Jigs and Fixtures
    • 3.1.3. Drill Bits and Drill Components
    • 3.1.4. Sensors and Associated Housings in Oil and Gas Components
    • 3.1.5. Combustion Systems and Turbomachinery
    • 3.1.6. Valve Fittings and Pump Components
    • 3.1.7. Heat Exchangers in Natural Gas Compression Systems
    • 3.1.8. Components for Gas Processing and Refinery Operations
    • 3.1.9. Catalytic Reactors and Components
    • 3.1.10. Downhole Applications and Complex Hydraulic Manifolds
    • 3.1.11. Crane Hooks, Propellers and Other Large Parts
  • 3.2. Overview of the AM Product and Process Lifecycle
  • 3.3. The Role of Design Optimization in AM
    • 3.3.1. Basics of DfAM (Design for Additive Manufacturing)
    • 3.3.2. Part Design and 3D CAD File Generation Software
  • 3.4. AM Parts Demand in Oil and Gas
    • 3.4.1. Application Cases for Prototypes and Models
    • 3.4.2. Application Cases for Part Replacement and Final Parts
      • 3.4.2.1. Accelerating Adoption Through Supplier Partnerships
      • 3.4.2.2. Evident Benefits of On-Demand Part Replacement and Application Cases
  • 3.5. Ten-year Forecast for 3D Printed Parts in the Oil and Gas Industry
    • 3.6.1. Ten-year Forecast for 3D Printed Metal Parts in Oil and Gas
      • 3.6.1.1. Metal Prototypes Rising to a Plateau
      • 3.6.1.2. Metal 3D Printed Tools and Casts for Indirect Production, a Transitory Opportunity
      • 3.6.1.3. Metal 3D Printed Replacement Parts Are a Key Opportunity for Medium and Long Term
      • 3.6.1.4. The Long-term Opportunity for Distributed, On-demand Mass Production of Optimized Parts by Additive Manufacturing
    • 3.6.2. Ten-year Forecast for 3D Printed Polymer Parts in Oil and Gas
      • 3.6.2.1. Prototypes and Models, Two Faces of the Same Application for Polymer AM Technologies
      • 3.6.2.2. Polymer 3D Printed Tools and Casts for Indirect Production
      • 3.6.2.3. End-use Polymer 3D Printed Parts Highly Dependent on High Performance Material Availability and Price
  • 3.7. Key Points from This Chapter

Chapter Four: OEC Companies and AM Services Profiles in the Oil and Gas Supply Chain

  • 4.1. Recent Activity in AM by OEC Firms
    • 4.1.1. Saudi Aramco
    • 4.1.2. Sinopec Group
    • 4.1.3. China National Petroleum Corporation
    • 4.1.4. Royal Dutch Shell
    • 4.1.5. BP
    • 4.1.6. Total
  • 4.2. Recent Activity in AM by Key Oil and Gas Industry Suppliers and Stakeholders
    • 4.2.1. General Electric
    • 4.2.2. Siemens
    • 4.2.3. DNV GL
    • 4.2.4. Lloyd's Register
    • 4.2.5. Recent AM Activities by Other Relevant Oil and Gas Suppliers and Stakeholders
      • 4.2.5.1. voestalpine Oil and Gas
      • 4.2.5.2. Repsol
      • 4.2.5.3. Woodside
      • 4.2.5.4. Wilhelmsen and Ivaldi Group
      • 4.2.5.5. Kennametal
      • 4.2.5.6. Aidro
      • 4.2.5.7. Wartsila
      • 4.2.5.8. Equinor
      • 4.2.5.9. Trelleborg
  • 4.3. Forecast for Additive Manufacturing Service Revenues in the Oil and Gas Industry
    • 4.3.1. Prototyping and Modeling Services for the Oil and Gas Industry
    • 4.3.2. Additively Manufactured Tooling Services for the Oil and Gas Industry
    • 4.3.3. Replacement, Repair and Remanufacturing 3D Printing Services for the Oil and Gas Industry
    • 4.3.4. AM Mass Production Services for the Oil and Gas Industry
  • 4.4. Key Points from This Chapter
  • About SmarTech Analysis
  • About the Analyst
  • Acronyms and Abbreviations Used In this Report

List of Exhibits

  • Exhibit 1-1: Using AM to Address Oil and Gas' Biggest Challenges
  • Exhibit 1-2: SmarTech Analysis's Additive Manufacturing Adoption Model for Oil and Gas Markets
  • Exhibit 1-3: Overall AM Revenues in The Oil and Gas Market by Primary Segments 2018 - 2029
  • Exhibit 1-4: Ten-year forecast for AM Revenues ($USM) in Oil and Gas by Segment 2018 - 2029
  • Exhibit 1-5: Expected 11-year Subsegment CAGR for AM in Oil and Gas
  • Exhibit 2-1: AM Technologies Considered for AM Hardware Forecast in this Report
  • Exhibit 2-2: All AM Hardware Unit Sales and YoY Growth Rate 2018 - 2029
  • Exhibit 2-3: Estimated Average Price Variation for AM Hardware Sold into Oil and Gas Industry
  • Exhibit 2-4: All AM Hardware Revenues ($USM) 2018 - 2029 by AM Technology Type
  • Exhibit 2-5: AM Hardware Revenues ($USM) CAGR by Technology in Oil and Gas 2018 - 2029
  • Exhibit 2-6: Comparison of Metal and Polymer AM Hardware Unit Sales 2018 - 2029
  • Exhibit 2-7: Comparison of Metal and Polymer AM Hardware Revenues ($USM) 2018 - 2029
  • Exhibit 2-8: Metal AM Processes Used in Oil and Gas and System Manufacturers
  • Exhibit 2-9: Comparison of Metal AM Hardware Unit Sales by Technology 2018 - 2029
  • Exhibit 2-10: Comparison of Metal AM Hardware Revenues ($USM) by Technology 2018 - 2029
  • Exhibit 2-11: Primary Polymer AM Processes and System Manufacturers
  • Exhibit 2-12: Comparison of Polymer AM Hardware Unit Sales by Technology 2018 - 2029
  • Exhibit 2-13: Comparison of Metal AM Hardware Revenues ($USM) by Technology 2018 - 2029
  • Exhibit 2-14: Key Identified Metal AM Material Development Initiatives by Print Technology
  • Exhibit 2-15: Trend for AM Materials Demand in Oil and Gas by AM Technology
  • Exhibit 2-16: Trend for AM Materials Revenues ($US) in Oil and Gas by AM Technology 2018 - 2029
  • Exhibit 2-17: Comparison of Polymer and Metal Materials Demand in Oil and Gas
  • Exhibit 2-18: Comparison of Polymer and Metal Materials Revenues in Oil and Gas
  • Exhibit 2-19: Summary of Most Common Types of Steel Additive Manufacturing Powders and Processes
  • Exhibit 2-20: Demand of Metal Materials in Oil and Gas (Kg) by AM Technology
  • Exhibit 2-21: Metal Material Revenues in Oil and Gas ($USM) by AM Technology
  • Exhibit 2-22: Demand of Metal Powders (Metric Tonnes) for Powder Bed Fusion 2018 2029
  • Exhibit 2-23: Powder Bed Fusion Metal Powders Revenues ($USM) 2018 2029 in Oil and Gas
  • Exhibit 2-24: Demand of Metal Powders (Kg) for DED Processes 2018 2029
  • Exhibit 2-25: DED Metal Materials Revenues ($USM) 2018 2029
  • Exhibit 2-26: Demand of Metal Powders (Kg) for Binder Jetting 2018 2029
  • Exhibit 2-27: Binder Jetting Metal Powders Revenues ($US) 2018 2029
  • Exhibit 2-28: Demand of Supersonic Consolidation/Cold Blown Metal Powders (Metric Tonnes) 2018-2029
  • Exhibit 2-29: Supersonic Consolidation/Cold Blown Metal Powders Revenues ($USM) 2018-2029
  • Exhibit 2-30: Demand of Polymer Materials in Oil and Gas (Metric Tonnes) by AM Technology
  • Exhibit 2-31: All Polymer Material Revenues in Oil and Gas ($USM) by AM Technology
  • Exhibit 2-32: Demand of Polymer Thermoplastics (Metric Tonnes) for Filament Extrusion Processes 2018 - 2029
  • Exhibit 2-33: Thermoplastic Filament Revenues ($USM) 2018 - 2029 in Oil and Gas
  • Exhibit 2-34: Large Format Additive Manufacturing Systems (LFAM)
  • Exhibit 2-35: Demand of Thermoplastic Pellets (Kg) for Material Extrusion Processes 2018-2029
  • Exhibit 2-36: Thermoplastic Revenues ($US) for Material Extrusion Processes in Oil and Gas 2018-2029
  • Exhibit 2-37: Demand of Photopolymer Resins (Kg) for Stereolithographic and Material Jetting Processes 2018-2029
  • Exhibit 2-38: Photopolymer Resin Revenues ($USM) for Stereolithographic and Material Jetting Processes 2018 - 2029
  • Exhibit 2-39: Demand of Thermoplastic Powders (Kg) for PBF Processes in Oil and Gas 2018 - 2029
  • Exhibit 2-40: Thermoplastic Powders Revenues ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 2-41: Ceramics Demand (Kg) in Oil and Gas 2018 - 2029
  • Exhibit 2-42: Ceramics Revenues ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-1: Typical 3D-printed Oil and Gas Parts and Relative Size and Weight
  • Exhibit 3-2: Typical Lifecycle for Materials/Products Produced Through Additive Manufacturing
  • Exhibit 3-3: Benefits of Rapid Prototyping
  • Exhibit 3-4: Demand Trend for 3D-printed Parts in Oil and Gas 2018 - 2029 by Material
  • Exhibit 3-5: Revenue Trend for 3D-printed Parts in Oil and Gas 2018 - 2029 by Material
  • Exhibit 3-6: Demand Trend of 3D-printed Parts in Oil and Gas 2018 - 2029 by Part Type
  • Exhibit 3-7: Revenues Trend of 3D-printed Parts in Oil and Gas 2018 - 2029 by Part Type
  • Exhibit 3-8: Expected CAGR for 3D-printed Part Sub-segments ($USM) 2018 - 2029
  • Exhibit 3-9: Number of Metal 3D-printed Parts ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-10: Value of Metal 3D-printed Parts ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-11: Number of Metal 3D-printed Prototypes in Oil and Gas 2018 - 2029
  • Exhibit 3-12: Value of Metal 3D-printed Prototypes ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-13: Number of Metal 3D-printed Tools in Oil and Gas 2018 - 2029
  • Exhibit 3-14: Value of Metal 3D-printed Tools ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-15: Number of Metal 3D-printed Replacement Parts in Oil and Gas 2018 - 2029
  • Exhibit 3-16: Value of Metal 3D-printed Replacement Parts ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-17: Number of Metal End-use Parts in Oil and Gas 2018 - 2029
  • Exhibit 3-18: Value of Metal 3D-printed End-use Parts ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-19: Number of Polymer 3D-printed Parts ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-20: Value of Polymer 3D-printed Parts ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-21: Number of Polymer 3D-printed Prototypes in Oil and Gas 2018 - 2029
  • Exhibit 3-22: Value of Polymer 3D-printed Prototypes ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-23: Number of Polymer 3D-printed Tools in Oil and Gas 2018 - 2029
  • Exhibit 3-24: Value of Polymer 3D-printed Tools ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 3-25: Number of 3D-printed Polymer End-use Parts in Oil and Gas 2018 - 2029
  • Exhibit 3-26: Value of Polymer 3D-printed End-use Parts ($USM) in Oil and Gas 2018 - 2029
  • Exhibit 4-1: Revenues from 3D-printed Prototype and Models Services by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-2: Revenues from Metal 3D-printed Prototypes by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-3: Revenues from Polymer 3D-printed Prototypes and Models by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-4: Revenues from 3D-printed Tools by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-5: Revenues from Metal 3D-printed Tools by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-6: Revenues from Polymer 3D-printed Tools by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-7: Revenues from 3D-printed Replacement Parts by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-8: Revenues from 3D-printed End-use Parts by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-9: Revenues from Metal 3D-printed End-use Parts by Supplier Type in Oil and Gas 2018 - 2029
  • Exhibit 4-10: Revenues from Polymer 3D-printed End-use Parts by Supplier Type in Oil and Gas 2018 - 2029
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