封面
市场调查报告书
商品编码
1818009

2032年工业自动化积层製造技术市场预测:按组件、材料类型、技术、应用、最终用户和地区进行的全球分析

Additive Manufacturing for Industrial Automation Market Forecasts to 2032 - Global Analysis By Component (Hardware, Software and Services), Material Type, Technology, Application, End User and By Geography

出版日期: | 出版商: Stratistics Market Research Consulting | 英文 200+ Pages | 商品交期: 2-3个工作天内

价格

根据 Stratistics MRC 的数据,全球工业自动化增材製造技术市场预计在 2025 年达到 49.1 亿美元,到 2032 年将达到 130 亿美元,预测期内的复合年增长率为 14.9%。

积层製造技术正在重塑工业自动化,透过提供适应性、精度和生产效率。利用先进的 3D 列印方法,製造商可以创建复杂的设计,同时最大限度地减少材料使用,加快原型製作速度并提高创造性灵活性。这种整合透过减少停机时间、优化物流和减少对传统技术的依赖来增强自动化。在自动化设定中,积层积层製造支援快速、按需生产替换零件和客製化工具,从而提高生产力。积层製造技术与自动化之间的协同作用正在创造创新机会,推动产业走向更智慧、更精简、更永续的营运。

根据 ASTM 国际标准,增材製造被定义为将材料(通常逐层)连接起来以从 3D 模型数据创建物体的过程,并且正在通过 ASTM F42 委员会进行标准化,该委员会已製定了 30 多项标准,实现 AM 技术与工业自动化系统之间的互通性,促进航太、汽车和医疗设备等多个领域的可扩展部署。

成本效益和减少废弃物

积层製造的成本效益是其在工业自动化领域广泛应用的关键因素。与传统的减材製造技术相比,积层製造采用逐层製造方法,最大限度地减少了材料浪费,从而提高了资源利用率并降低了原材料成本。这种永续的方法还能降低能源消耗,进一步节省营运成本。自动化设定透过减少人工需求和设备停机时间,进一步提升了成本效益。该技术使製造商能够交付精准且错误更少的零件,从而提高了效率。积层製造成本低且品质高,使其成为注重效率和竞争力的产业不可或缺的技术。

初期投资成本高

高昂的设置成本是积层製造技术在工业自动化领域推广的关键障碍。先进的3D列印系统、专业软体和配套基础设施需要大量投资,中小企业难以管理。这些资金需求使得许多公司,尤其是预算有限的中小企业,难以采用该技术。虽然积层製造有望带来长期效率和成本节约,但由于投资回报速度的不确定性,製造商对此持谨慎态度。因此,高昂的初始成本阻碍了其与自动化生产设备的集成,对市场成长构成了重大障碍。

材料科学进展

材料科学的进步为积层製造技术在工业自动化领域的应用创造了巨大的机会。先进聚合物、复合材料和金属粉末领域的突破正在拓展3D列印的应用范围。强度、耐久性和导电性均有所提升的材料,正助力航太和汽车等高要求产业生产功能性零件。随着更多经济实惠且可靠的选择出现,积层製造正变得越来越切实可行,适合大规模应用。这些材料创新不仅降低了成本,还扩展了设计能力,并促进了更广泛的应用。持续的研究正在使积层製造技术能够更有效地整合到自动化製造系统中。

网路安全风险与资料窃取

工业自动化的积层製造技术因其依赖数位模型和互联网而面临严重的网路安全威胁。骇客可能窃取或篡改设计文件,从而导致智慧财产权损失和零件生产缺陷。在高度自动化的环境中,此类中断可能会中断工作流程、危及安全或损坏设备。这些风险降低了人们对大规模采用该技术的信心。随着工业4.0时代各行各业采用更互联的系统,恶意软体和勒索软体的漏洞也随之增加。如果没有强大的网路安全基础设施和安全的资料管理实践,积层製造仍然容易受到风险的影响,这些风险可能会损害其发展并扰乱自动化工业运作。

COVID-19的影响:

新冠疫情对工业自动化积层製造技术的影响既充满挑战,也带来了改变。最初,供应链中断和工厂关闭导致投资减少,应用放缓。然而,疫情也展现了积层製造的战略优势,尤其是其快速、分散式、按需生产关键零件和医疗用品的能力。这种能力缓解了短缺,并支持了自动化流程的连续性。危机过后,各行各业开始意识到这项技术所具备的韧性、灵活性和效率。因此,疫情加速了积层製造的长期应用,并将它定位为未来自动化的关键推动力。

预计硬体部分将成为预测期内最大的部分

预计硬体领域将在预测期内占据最大的市场份额,因为它提供了生产所需的核心机械设备。印表机、扫描器和相关工具是建立精密、复杂和高效组件的基础。自动化环境依赖于能够顺利整合到生产线的可靠硬体。多材料支援和更快的列印速度等技术创新正在推动对先进硬体解决方案的依赖。随着越来越多的产业需要耐用、高性能的系统来实现汽车、航太和医疗保健等领域的大规模应用,硬体将继续占据市场主导地位,并成为技术应用的基础。

复合材料领域预计将在预测期内实现最高复合年增长率

复合材料领域因其独特的性能组合,预计将在预测期内呈现最高成长率。复合材料具有优异的耐久性、高比强度和耐恶劣环境性能,在汽车、航太和工业设备等应用中广受欢迎。在自动化环境中,复合材料能够生产轻盈、坚固的零件,从而提高性能并降低能耗。其设计灵活性也使其能够创建适合现代製造需求的复杂客製化结构。随着基于复合材料的列印方法的不断改进,该领域正在迅速扩张,并已稳居市场成长最快的地位。

占比最大的地区:

预计北美将在预测期内占据最大的市场份额。这得归功于其先进的基础设施、新技术的快速应用以及大型跨国公司的存在。在航太、医疗保健和汽车等领域的大量研发投资正在巩固该地区的地位。这些产业需要高度客製化和精密的零件,而积层製造可以有效率地满足这些需求。政府推出的鼓励采用自动化和智慧工厂的支持性政策也推动了成长。该地区早期向工业 4.0 的转变,加上成熟的製造商和创新者,确保了其市场主导。北美继续占据主导地位,并为全球扩张设定步伐。

复合年增长率最高的地区:

受快速的工业成长、不断扩张的智慧工厂计划以及利好的政府政策支撑,预计亚太地区在预测期内将呈现最高的复合年增长率。中国、日本、韩国和印度等国家正在加速对数位化和先进製造技术的投资。汽车、医疗保健和家电等行业日益增长的应用,推动了自动化设备对积层製造解决方案的更大依赖。此外,经济高效的生产基地、技术娴熟的人才库以及不断发展的新兴企业生态系统也进一步增强了积层製造技术的采用。这些因素共同作用,使亚太地区成为最具活力、成长最快的区域市场之一。

免费客製化服务:

此报告的订阅者可以使用以下免费自订选项之一:

  • 公司简介
    • 对最多三家其他市场公司进行全面分析
    • 主要企业的SWOT分析(最多3家公司)
  • 区域细分
    • 根据客户兴趣对主要国家进行的市场估计、预测和复合年增长率(註:基于可行性检查)
  • 竞争基准化分析
    • 根据产品系列、地理分布和策略联盟对主要企业基准化分析

目录

第一章执行摘要

第二章 前言

  • 概述
  • 相关利益者
  • 调查范围
  • 调查方法
    • 资料探勘
    • 数据分析
    • 数据检验
    • 研究途径
  • 研究材料
    • 主要研究资料
    • 次级研究资讯来源
    • 先决条件

第三章市场走势分析

  • 驱动程式
  • 抑制因素
  • 机会
  • 威胁
  • 技术分析
  • 应用分析
  • 最终用户分析
  • 新兴市场
  • COVID-19的影响

第四章 波特五力分析

  • 供应商的议价能力
  • 买方的议价能力
  • 替代品的威胁
  • 新进入者的威胁
  • 竞争对手之间的竞争

5. 工业自动化积层製造技术市场(按组件)

  • 硬体
  • 软体
  • 服务

6. 工业自动化积层製造技术市场(依材料类型)

  • 金属
  • 聚合物
  • 陶瓷
  • 复合材料
  • 光聚合物
  • 生物材料

7. 工业自动化积层製造技术市场(按技术)

  • 熔融沈积成型(FDM)
  • 选择性雷射烧结(SLS)
  • 立体光固成型(SLA)
  • 直接金属雷射烧结(DMLS)
  • 电子束熔炼(EBM)
  • 黏着剂喷涂成型
  • 材料喷涂
  • 数位光处理 (DLP)
  • 混合积层製造

8. 工业自动化积层製造技术市场(依应用)

  • 快速原型製作
  • 工具及固定装置
  • 最终用途生产零件
  • 备件製造
  • 大规模客製化
  • 功能测试
  • 自动化后处理
  • 自动化品质检测

9. 工业自动化积层製造技术市场(依最终用户)

  • 航太/国防
  • 电子和半导体
  • 工业机械和设备
  • 能源与公共产业
  • 医疗保健和医疗设备
  • 消费品
  • 建筑与建筑
  • 教育研究所

10. 全球工业自动化积层製造技术市场(按地区)

  • 北美洲
    • 美国
    • 加拿大
    • 墨西哥
  • 欧洲
    • 德国
    • 英国
    • 义大利
    • 法国
    • 西班牙
    • 其他欧洲国家
  • 亚太地区
    • 日本
    • 中国
    • 印度
    • 澳洲
    • 纽西兰
    • 韩国
    • 其他亚太地区
  • 南美洲
    • 阿根廷
    • 巴西
    • 智利
    • 南美洲其他地区
  • 中东和非洲
    • 沙乌地阿拉伯
    • 阿拉伯聯合大公国
    • 卡达
    • 南非
    • 其他中东和非洲地区

第十一章 重大进展

  • 协议、伙伴关係、合作和合资企业
  • 收购与合併
  • 新产品发布
  • 业务扩展
  • 其他关键策略

第十二章 公司概况

  • UPTIVE Advanced Manufacturing
  • Stratasys
  • EOS
  • 3D Systems, Inc.
  • Materialise
  • Renishaw
  • Sinterit
  • Proto Labs
  • Grenzebach
  • Siemens Energy
  • KUKA
  • AM-Flow
  • Printinue
  • Rockwell Automation
  • ABB
Product Code: SMRC30972

According to Stratistics MRC, the Global Additive Manufacturing for Industrial Automation Market is accounted for $4.91 billion in 2025 and is expected to reach $13.00 billion by 2032 growing at a CAGR of 14.9% during the forecast period. Additive manufacturing is reshaping industrial automation by offering adaptability, precision, and efficiency in production. Using advanced 3D printing methods, manufacturers can produce intricate designs with minimal material use, accelerated prototyping, and greater creative flexibility. This integration enhances automation by cutting downtime, optimizing logistics, and lowering reliance on conventional techniques. Within automated setups, additive manufacturing supports quick, on-demand fabrication of replacement parts and tailored tools, boosting productivity. The synergy of additive manufacturing and automation is creating innovative opportunities, propelling industries toward smarter, leaner, and more sustainable operations.

According to ASTM International, Additive Manufacturing is defined as the process of joining materials to make objects from 3D model data, usually layer upon layer, and is increasingly being standardized through the ASTM F42 Committee. This committee has developed over 30 standards that enable interoperability between AM technologies and industrial automation systems, facilitating scalable deployment across sectors like aerospace, automotive, and medical devices.

Market Dynamics:

Driver:

Cost efficiency and waste reduction

The cost-effectiveness of additive manufacturing is a crucial factor driving its adoption in industrial automation. By using a layer-by-layer approach, it minimizes material waste compared to traditional subtractive techniques, leading to better resource utilization and reduced raw material costs. This sustainable method also cuts down energy usage, creating additional operational savings. Within automated setups, cost benefits are amplified by lowering manual labor needs and minimizing equipment downtime. The technology enables manufacturers to deliver accurate parts with reduced errors, enhancing efficiency. Offering low-cost yet high-quality output, additive manufacturing serves as a vital enabler for industries focusing on efficiency and competitiveness.

Restraint:

High initial investment costs

High setup costs present a critical barrier to the expansion of additive manufacturing in industrial automation. Advanced 3D printing systems, specialized software, and supporting infrastructure require heavy investment, which smaller businesses find difficult to manage. Beyond the purchase price, ongoing maintenance, upgrades, and operator training add extra expenses. These financial demands make adoption challenging for many firms, especially SMEs with limited budgets. Although additive manufacturing promises long-term efficiency and savings, uncertainty around the speed of return on investment makes manufacturers cautious. The steep initial cost therefore slows integration into automated production setups, acting as a major obstacle to market growth.

Opportunity:

Advancements in material science

The evolution of material science is opening significant opportunities for additive manufacturing in industrial automation. Breakthroughs in advanced polymers, composites, and metallic powders are widening the range of 3D-printed applications. Materials with enhanced strength, durability, and conductivity now make it possible to produce functional components for industries with strict performance demands, such as aerospace and automotive. With an increasing variety of affordable and reliable options, additive manufacturing is becoming more practical for large-scale use. These material innovations not only lower costs but also expand design capabilities, driving broader adoption. Continuous research ensures additive technologies integrate more effectively into automated manufacturing systems.

Threat:

Cyber security risks and data theft

Additive manufacturing in industrial automation faces significant cybersecurity threats due to its reliance on digital models and connected networks. Hackers can steal or alter design files, risking intellectual property losses or the creation of defective components. In highly automated settings, such disruptions could interrupt workflows, compromise safety, or damage equipment. These risks weaken confidence in adopting the technology at scale. As industries adopt more interconnected systems under Industry 4.0, vulnerabilities to malware or ransomware increase. Without robust cybersecurity infrastructure and secure data management practices, additive manufacturing remains exposed to risks that could undermine its growth and disrupt automated industrial operations.

Covid-19 Impact:

The impact of COVID-19 on additive manufacturing in industrial automation was both challenging and transformative. During the early stages, disruptions in supply chains and factory closures led to reduced investments and slowed implementation. Yet, the pandemic also showcased the strategic benefits of additive manufacturing, particularly its ability to provide rapid, decentralized, and on-demand production of critical components and medical supplies. This capability helped mitigate shortages and supported continuity in automated processes. Following the crisis, industries began valuing the resilience, flexibility, and efficiency offered by the technology. As a result, the pandemic accelerated long-term adoption, positioning additive manufacturing as a key enabler for future automation.

The hardware segment is expected to be the largest during the forecast period

The hardware segment is expected to account for the largest market share during the forecast period as it provides the core machines and equipment necessary for production. Printers, scanners, and related tools are fundamental to building precise, complex, and efficient components. Automation environments depend on reliable hardware to integrate smoothly into production lines. Innovations such as multi-material capabilities and faster printing speeds are driving further reliance on advanced hardware solutions. With industries increasingly seeking durable and high-performance systems for large-scale applications in areas like automotive, aerospace, and healthcare, hardware continues to dominate the market, serving as the foundation for technological adoption.

The composites segment is expected to have the highest CAGR during the forecast period

Over the forecast period, the composites segment is predicted to witness the highest growth rate because of their unique combination of properties. They offer excellent durability, strength-to-weight ratio, and resistance to harsh conditions, making them valuable for applications in automotive, aerospace, and industrial equipment. In automated settings, composites enable the production of lightweight, robust components that improve performance while lowering energy use. Their flexibility in design also allows the creation of intricate, tailored structures suited to modern manufacturing demands. With ongoing improvements in composite-based printing methods, this segment is expanding rapidly, establishing itself as the fastest-growing area in the market.

Region with largest share:

During the forecast period, the North America region is expected to hold the largest market share, driven by advanced infrastructure, rapid adoption of new technologies, and the presence of major global players. Significant investments in research and development across sectors such as aerospace, healthcare, and automotive strengthen the region's position. These industries demand highly customized and precise components, which additive manufacturing provides efficiently. Supportive government policies that encourage automation and smart factory adoption also boost growth. The region's early shift toward Industry 4.0, coupled with established manufacturers and innovators, ensures its market leadership. North America continues to dominate, setting the pace for global expansion.

Region with highest CAGR:

Over the forecast period, the Asia Pacific region is anticipated to exhibit the highest CAGR, supported by rapid industrial growth, expanding smart factory initiatives, and favorable government policies. Nations such as China, Japan, South Korea, and India are accelerating investments in digital and advanced manufacturing technologies. Rising applications in industries like automotive, healthcare, and consumer electronics are increasing reliance on additive solutions within automated setups. Additionally, the presence of cost-effective production hubs, a skilled talent pool, and growing startup ecosystems further strengthen adoption. These factors collectively make Asia-Pacific the most dynamic and rapidly expanding regional market.

Key players in the market

Some of the key players in Additive Manufacturing for Industrial Automation Market include UPTIVE Advanced Manufacturing, Stratasys, EOS, 3D Systems, Inc., Materialise, Renishaw, Sinterit, Proto Labs, Grenzebach, Siemens Energy, KUKA, AM-Flow, Printinue, Rockwell Automation and ABB.

Key Developments:

In August 2025, 3D Systems announced it has been awarded a $7.65 million U.S. Air Force contract for a Large-format Metal 3D Printer Advanced Technology Demonstrator. The award is the next phase of a program 3D Systems has worked on since 2023 that supports the development of large-scale, high-speed, flight relevant additive manufacturing print capabilities.

In August 2025, Eos Energy Enterprises has signed a memorandum of understanding (MoU) with Frontier Power for a 5 gigawatt-hour (GWh) energy storage framework agreement. The partnership marks Eos' entry into the UK market, utilising its zinc-based long-duration energy storage systems.

In February 2025, Renishaw have established a new Renishaw Solutions Centre in Spain. Located within the premises of IDEKO, the new facility forms part of a collaboration agreement signed between the two organisations at the 2024 International Machine Tool Exhibition in Bilbao, Spain.

Components Covered:

  • Hardware
  • Software
  • Services

Material Types Covered:

  • Metals
  • Polymers
  • Ceramics
  • Composites
  • Photopolymers
  • Biomaterials

Technologies Covered:

  • Fused Deposition Modeling (FDM)
  • Selective Laser Sintering (SLS)
  • Stereolithography (SLA)
  • Direct Metal Laser Sintering (DMLS)
  • Electron Beam Melting (EBM)
  • Binder Jetting
  • Material Jetting
  • Digital Light Processing (DLP)
  • Hybrid Additive Manufacturing

Applications Covered:

  • Rapid Prototyping
  • Tooling and Fixtures
  • End-Use Production Parts
  • Spare Parts Manufacturing
  • Mass Customization
  • Functional Testing
  • Post-Processing Automation
  • Quality Inspection Automation

End Users Covered:

  • Automotive
  • Aerospace & Defense
  • Electronics & Semiconductors
  • Industrial Machinery & Equipment
  • Energy & Utilities
  • Healthcare & Medical Devices
  • Consumer Goods
  • Construction & Architecture
  • Education & Research Institutions

Regions Covered:

  • North America
    • US
    • Canada
    • Mexico
  • Europe
    • Germany
    • UK
    • Italy
    • France
    • Spain
    • Rest of Europe
  • Asia Pacific
    • Japan
    • China
    • India
    • Australia
    • New Zealand
    • South Korea
    • Rest of Asia Pacific
  • South America
    • Argentina
    • Brazil
    • Chile
    • Rest of South America
  • Middle East & Africa
    • Saudi Arabia
    • UAE
    • Qatar
    • South Africa
    • Rest of Middle East & Africa

What our report offers:

  • Market share assessments for the regional and country-level segments
  • Strategic recommendations for the new entrants
  • Covers Market data for the years 2024, 2025, 2026, 2028, and 2032
  • Market Trends (Drivers, Constraints, Opportunities, Threats, Challenges, Investment Opportunities, and recommendations)
  • Strategic recommendations in key business segments based on the market estimations
  • Competitive landscaping mapping the key common trends
  • Company profiling with detailed strategies, financials, and recent developments
  • Supply chain trends mapping the latest technological advancements

Free Customization Offerings:

All the customers of this report will be entitled to receive one of the following free customization options:

  • Company Profiling
    • Comprehensive profiling of additional market players (up to 3)
    • SWOT Analysis of key players (up to 3)
  • Regional Segmentation
    • Market estimations, Forecasts and CAGR of any prominent country as per the client's interest (Note: Depends on feasibility check)
  • Competitive Benchmarking
    • Benchmarking of key players based on product portfolio, geographical presence, and strategic alliances

Table of Contents

1 Executive Summary

2 Preface

  • 2.1 Abstract
  • 2.2 Stake Holders
  • 2.3 Research Scope
  • 2.4 Research Methodology
    • 2.4.1 Data Mining
    • 2.4.2 Data Analysis
    • 2.4.3 Data Validation
    • 2.4.4 Research Approach
  • 2.5 Research Sources
    • 2.5.1 Primary Research Sources
    • 2.5.2 Secondary Research Sources
    • 2.5.3 Assumptions

3 Market Trend Analysis

  • 3.1 Introduction
  • 3.2 Drivers
  • 3.3 Restraints
  • 3.4 Opportunities
  • 3.5 Threats
  • 3.6 Technology Analysis
  • 3.7 Application Analysis
  • 3.8 End User Analysis
  • 3.9 Emerging Markets
  • 3.10 Impact of Covid-19

4 Porters Five Force Analysis

  • 4.1 Bargaining power of suppliers
  • 4.2 Bargaining power of buyers
  • 4.3 Threat of substitutes
  • 4.4 Threat of new entrants
  • 4.5 Competitive rivalry

5 Global Additive Manufacturing for Industrial Automation Market, By Component

  • 5.1 Introduction
  • 5.2 Hardware
  • 5.3 Software
  • 5.4 Services

6 Global Additive Manufacturing for Industrial Automation Market, By Material Type

  • 6.1 Introduction
  • 6.2 Metals
  • 6.3 Polymers
  • 6.4 Ceramics
  • 6.5 Composites
  • 6.6 Photopolymers
  • 6.7 Biomaterials

7 Global Additive Manufacturing for Industrial Automation Market, By Technology

  • 7.1 Introduction
  • 7.2 Fused Deposition Modeling (FDM)
  • 7.3 Selective Laser Sintering (SLS)
  • 7.4 Stereolithography (SLA)
  • 7.5 Direct Metal Laser Sintering (DMLS)
  • 7.6 Electron Beam Melting (EBM)
  • 7.7 Binder Jetting
  • 7.8 Material Jetting
  • 7.9 Digital Light Processing (DLP)
  • 7.10 Hybrid Additive Manufacturing

8 Global Additive Manufacturing for Industrial Automation Market, By Application

  • 8.1 Introduction
  • 8.2 Rapid Prototyping
  • 8.3 Tooling and Fixtures
  • 8.4 End-Use Production Parts
  • 8.5 Spare Parts Manufacturing
  • 8.6 Mass Customization
  • 8.7 Functional Testing
  • 8.8 Post-Processing Automation
  • 8.9 Quality Inspection Automation

9 Global Additive Manufacturing for Industrial Automation Market, By End User

  • 9.1 Introduction
  • 9.2 Automotive
  • 9.3 Aerospace & Defense
  • 9.4 Electronics & Semiconductors
  • 9.5 Industrial Machinery & Equipment
  • 9.6 Energy & Utilities
  • 9.7 Healthcare & Medical Devices
  • 9.8 Consumer Goods
  • 9.9 Construction & Architecture
  • 9.10 Education & Research Institutions

10 Global Additive Manufacturing for Industrial Automation Market, By Geography

  • 10.1 Introduction
  • 10.2 North America
    • 10.2.1 US
    • 10.2.2 Canada
    • 10.2.3 Mexico
  • 10.3 Europe
    • 10.3.1 Germany
    • 10.3.2 UK
    • 10.3.3 Italy
    • 10.3.4 France
    • 10.3.5 Spain
    • 10.3.6 Rest of Europe
  • 10.4 Asia Pacific
    • 10.4.1 Japan
    • 10.4.2 China
    • 10.4.3 India
    • 10.4.4 Australia
    • 10.4.5 New Zealand
    • 10.4.6 South Korea
    • 10.4.7 Rest of Asia Pacific
  • 10.5 South America
    • 10.5.1 Argentina
    • 10.5.2 Brazil
    • 10.5.3 Chile
    • 10.5.4 Rest of South America
  • 10.6 Middle East & Africa
    • 10.6.1 Saudi Arabia
    • 10.6.2 UAE
    • 10.6.3 Qatar
    • 10.6.4 South Africa
    • 10.6.5 Rest of Middle East & Africa

11 Key Developments

  • 11.1 Agreements, Partnerships, Collaborations and Joint Ventures
  • 11.2 Acquisitions & Mergers
  • 11.3 New Product Launch
  • 11.4 Expansions
  • 11.5 Other Key Strategies

12 Company Profiling

  • 12.1 UPTIVE Advanced Manufacturing
  • 12.2 Stratasys
  • 12.3 EOS
  • 12.4 3D Systems, Inc.
  • 12.5 Materialise
  • 12.6 Renishaw
  • 12.7 Sinterit
  • 12.8 Proto Labs
  • 12.9 Grenzebach
  • 12.10 Siemens Energy
  • 12.11 KUKA
  • 12.12 AM-Flow
  • 12.13 Printinue
  • 12.14 Rockwell Automation
  • 12.15 ABB

List of Tables

  • Table 1 Global Additive Manufacturing for Industrial Automation Market Outlook, By Region (2024-2032) ($MN)
  • Table 2 Global Additive Manufacturing for Industrial Automation Market Outlook, By Component (2024-2032) ($MN)
  • Table 3 Global Additive Manufacturing for Industrial Automation Market Outlook, By Hardware (2024-2032) ($MN)
  • Table 4 Global Additive Manufacturing for Industrial Automation Market Outlook, By Software (2024-2032) ($MN)
  • Table 5 Global Additive Manufacturing for Industrial Automation Market Outlook, By Services (2024-2032) ($MN)
  • Table 6 Global Additive Manufacturing for Industrial Automation Market Outlook, By Material Type (2024-2032) ($MN)
  • Table 7 Global Additive Manufacturing for Industrial Automation Market Outlook, By Metals (2024-2032) ($MN)
  • Table 8 Global Additive Manufacturing for Industrial Automation Market Outlook, By Polymers (2024-2032) ($MN)
  • Table 9 Global Additive Manufacturing for Industrial Automation Market Outlook, By Ceramics (2024-2032) ($MN)
  • Table 10 Global Additive Manufacturing for Industrial Automation Market Outlook, By Composites (2024-2032) ($MN)
  • Table 11 Global Additive Manufacturing for Industrial Automation Market Outlook, By Photopolymers (2024-2032) ($MN)
  • Table 12 Global Additive Manufacturing for Industrial Automation Market Outlook, By Biomaterials (2024-2032) ($MN)
  • Table 13 Global Additive Manufacturing for Industrial Automation Market Outlook, By Technology (2024-2032) ($MN)
  • Table 14 Global Additive Manufacturing for Industrial Automation Market Outlook, By Fused Deposition Modeling (FDM) (2024-2032) ($MN)
  • Table 15 Global Additive Manufacturing for Industrial Automation Market Outlook, By Selective Laser Sintering (SLS) (2024-2032) ($MN)
  • Table 16 Global Additive Manufacturing for Industrial Automation Market Outlook, By Stereolithography (SLA) (2024-2032) ($MN)
  • Table 17 Global Additive Manufacturing for Industrial Automation Market Outlook, By Direct Metal Laser Sintering (DMLS) (2024-2032) ($MN)
  • Table 18 Global Additive Manufacturing for Industrial Automation Market Outlook, By Electron Beam Melting (EBM) (2024-2032) ($MN)
  • Table 19 Global Additive Manufacturing for Industrial Automation Market Outlook, By Binder Jetting (2024-2032) ($MN)
  • Table 20 Global Additive Manufacturing for Industrial Automation Market Outlook, By Material Jetting (2024-2032) ($MN)
  • Table 21 Global Additive Manufacturing for Industrial Automation Market Outlook, By Digital Light Processing (DLP) (2024-2032) ($MN)
  • Table 22 Global Additive Manufacturing for Industrial Automation Market Outlook, By Hybrid Additive Manufacturing (2024-2032) ($MN)
  • Table 23 Global Additive Manufacturing for Industrial Automation Market Outlook, By Application (2024-2032) ($MN)
  • Table 24 Global Additive Manufacturing for Industrial Automation Market Outlook, By Rapid Prototyping (2024-2032) ($MN)
  • Table 25 Global Additive Manufacturing for Industrial Automation Market Outlook, By Tooling and Fixtures (2024-2032) ($MN)
  • Table 26 Global Additive Manufacturing for Industrial Automation Market Outlook, By End-Use Production Parts (2024-2032) ($MN)
  • Table 27 Global Additive Manufacturing for Industrial Automation Market Outlook, By Spare Parts Manufacturing (2024-2032) ($MN)
  • Table 28 Global Additive Manufacturing for Industrial Automation Market Outlook, By Mass Customization (2024-2032) ($MN)
  • Table 29 Global Additive Manufacturing for Industrial Automation Market Outlook, By Functional Testing (2024-2032) ($MN)
  • Table 30 Global Additive Manufacturing for Industrial Automation Market Outlook, By Post-Processing Automation (2024-2032) ($MN)
  • Table 31 Global Additive Manufacturing for Industrial Automation Market Outlook, By Quality Inspection Automation (2024-2032) ($MN)
  • Table 32 Global Additive Manufacturing for Industrial Automation Market Outlook, By End User (2024-2032) ($MN)
  • Table 33 Global Additive Manufacturing for Industrial Automation Market Outlook, By Automotive (2024-2032) ($MN)
  • Table 34 Global Additive Manufacturing for Industrial Automation Market Outlook, By Aerospace & Defense (2024-2032) ($MN)
  • Table 35 Global Additive Manufacturing for Industrial Automation Market Outlook, By Electronics & Semiconductors (2024-2032) ($MN)
  • Table 36 Global Additive Manufacturing for Industrial Automation Market Outlook, By Industrial Machinery & Equipment (2024-2032) ($MN)
  • Table 37 Global Additive Manufacturing for Industrial Automation Market Outlook, By Energy & Utilities (2024-2032) ($MN)
  • Table 38 Global Additive Manufacturing for Industrial Automation Market Outlook, By Healthcare & Medical Devices (2024-2032) ($MN)
  • Table 39 Global Additive Manufacturing for Industrial Automation Market Outlook, By Consumer Goods (2024-2032) ($MN)
  • Table 40 Global Additive Manufacturing for Industrial Automation Market Outlook, By Construction & Architecture (2024-2032) ($MN)
  • Table 41 Global Additive Manufacturing for Industrial Automation Market Outlook, By Education & Research Institutions (2024-2032) ($MN)

Note: Tables for North America, Europe, APAC, South America, and Middle East & Africa Regions are also represented in the same manner as above.