Market Forecast By Offerings (Hardware, Software and Services), By Process (Material Handling, Automated Production, Part Handling, Post Handling and Multiprocessing), By End Users (Defense, Healthcare, Industrial Manufacturing, Automotive, Customer Products, Energy and Others), By Regions (North America, Europe, Asia Pacific and Rest of World), By Key Countries and Competitive Landscape
Product Code: ETC000682 | Publication Date: Jul 2019 | Product Type: Report | |
Publisher: 6Wresearch | No. of Pages: 300 | No. of Figures: 90 | No. of Tables: 30 |
Report Name | Automated 3D Printing Market |
Report Category/Coverage | Global |
Forecast period | 2025-2031 |
CAGR | 9.8% |
Market Size | USD 5.1 billion by 2031 |
Growing Sector | Healthcare |
Automated 3D Printing Market report thoroughly covers the by offering, by process, by region and by end user. The market report provides an unbiased and detailed analysis of the ongoing market trends, opportunities/high growth areas, and market drivers which would help the stakeholders to devise and align their market strategies according to the current and future market dynamics.
The Automated 3D Printing Market has been experiencing significant growth over the past few years. As of 2024, the global market is valued at approximately $2.1 billion. Further, the Global Market is projected to expand at a CAGR of 9.8% from 2024 to 2030. Additionally, by 2030, the market size is expected to reach around $5.1 billion.
The automated 3D printing market is experiencing rapid growth driven by advancements in technology and increasing demand across various industries. Automated 3D printing integrates robotic systems and intelligent software, greatly enhancing efficiency, accuracy, and scalability in production processes. This innovation is transforming industries such as aerospace, healthcare, automotive, and consumer goods by enabling the mass production of complex parts with minimal human intervention. The market's expansion is further propelled by the constant push for cost-effective and time-efficient manufacturing solutions, along with the rising adoption of Industry 4.0 practices.
According to 6Wresearch, the Automated 3D Printing Market revenue is expected to reach at a significant CAGR of 9.8% during the forecast period 2025-2031. As companies strive to offer personalized products at competitive prices, automated 3D printing provides an efficient solution by enabling the production of customized parts with minimal additional costs. This technology's ability to rapidly prototype and produce low-volume, custom designs has spurred interest across sectors such as healthcare, automotive, and consumer goods, where specific design requirements are critical.
One of which is the high initial investment required for advanced 3D printing machinery and automation systems. Small to medium-sized enterprises (SMEs) may find it financially burdensome to adopt such technology, slowing market penetration. Additionally, issues related to the standardization of materials and processes further complicate the widespread adoption of automated 3D printing, necessitating ongoing research and development efforts to establish industry-wide standards.
Companies such as Stratasys and 3D Systems are pioneers in this space, consistently pushing the boundaries of what is possible with automated technologies. Desktop Metal is also a significant player, known for its advancements in speed and cost-effectiveness of 3D printing. Additionally, HP's entry into the market has further accelerated competition, as they leverage their expertise in traditional printing technologies to transform 3D printing. These leading companies, among others, are instrumental in shaping the future of manufacturing, reducing labor costs, and optimizing the production of complex parts across various industries.
As the automated 3D printing market continues to expand, governments worldwide are implementing various regulations to ensure safe and efficient integration of this technology into industries. These regulations often focus on several key areas, including safety standards, intellectual property protection, and environmental considerations. Safety standards are crucial to prevent workplace accidents and ensure the machinery operates within recommended parameters, minimizing risks to operators and their surroundings. Intellectual property laws are being adapted to address the challenges of replicability associated with 3D printing technology, ensuring that original designs are protected against unauthorized reproductions. Environmental regulations are also emerging to address the waste and energy consumption linked with 3D printing processes, promoting sustainable practices within the industry.
The future of the automated 3D printing market holds exciting possibilities as advancements in technology continue to evolve. As industries demand faster production times and cost-efficiency, automated 3D printing is set to become a staple in numerous sectors such as healthcare, automotive, and aerospace. With the integration of artificial intelligence and machine learning, 3D printers will soon be capable of self-optimizing, leading to increased precision and reduced material waste. Furthermore, the development of new materials and the improvement of data analytics tools will drive customization to new heights, allowing manufacturers to meet specific consumer needs with unprecedented accuracy.
The report offers a comprehensive study of the subsequent market segments and their leading categories.
According to Suryakant, Senior Research Analyst, 6wresearch, the software in the automated 3D printing market plays a critical role in streamlining and optimizing the printing process. It includes sophisticated computer-aided design (CAD) programs, slicing software, and print management platforms that collectively enhance efficiency and precision. CAD programs are essential for designing detailed models, providing the necessary tools for customization and complexity. Slicing software converts these models into instructions that 3D printers can understand, optimizing print paths and resource usage.
Material handling plays a crucial role in the automated 3D printing market, directly influencing efficiency, precision, and throughput. In an automated setup, the ability to seamlessly manage materials—be it resins, metals, or polymers—is key to maintaining a smooth production workflow. Advanced material handling systems are integrated to provide consistent material feed, minimize waste, and reduce the time between print jobs. Automation reduces human error, ensuring that materials are correctly loaded and monitored throughout the printing process. Moreover, developments in robotics and AI are enhancing these systems, allowing for predictive maintenance and automatic replenishment of materials.
The integration of automated 3D printing in the healthcare market is revolutionizing the industry by enhancing precision and efficiency in medical manufacturing. This technology allows for the production of customized medical devices, prosthetics, and even patient-specific implants with remarkable accuracy. Automated 3D printing reduces material waste and accelerates production times, making it a cost-effective solution for personalized healthcare needs. Moreover, the ability to rapidly prototype designs facilitates innovation in medical research and development, contributing to advanced treatments and improved patient outcomes.
North America is at the forefront of the automated 3D printing market, driven by technological advancements and innovation in the region. The demand for rapid prototyping, mass customization, and efficient supply chains has led industries such as aerospace, automotive, and healthcare to increasingly adopt 3D printing technologies. The strong presence of major technology companies and start-ups in the U.S. and Canada accelerates research and development, further enhancing the capabilities of 3D printing solutions. Additionally, supportive government policies and significant investments in automation technologies contribute to positioning North America as a leader in the global 3D printing landscape.
The market report has been segmented and sub segmented into the following categories:
1 Executive Summary |
2 Introduction |
2.1 Report Description |
2.2 Key Highlights of The Report |
2.3 Market Scope & Segmentation |
2.4 Research Methodology |
2.5 Assumptions |
3 Automated 3D Printing Market Overview |
3.1 Automated 3D Printing Market Revenues & Volume, 2021-2031F |
3.2 Automated 3D Printing Market Revenue Share, By Offering, 2021 & 2031F |
3.3 Automated 3D Printing Market Revenue Share, By Process, 2021 & 2031F |
3.4 Automated 3D Printing Market Revenue Share, By End User, 2021 & 2031F |
3.5 Automated 3D Printing Market Revenue Share, By Regions, 2021 & 2031F |
3.6 Automated 3D Printing Market Industry Life Cycle |
3.7 Automated 3D Printing Market- Porter’s Five Forces, 2024 |
4 Automated 3D Printing Market Dynamics |
4.1 Impact Analysis |
4.2 Market Drivers |
4.3 Market Restraints |
5 Automated 3D Printing Market Trends |
6 Automated 3D Printing Market Overview, By Offerings |
6.1 Automated 3D Printing Market Revenues & Volume, By Hardware, 2021-2031F |
6.2 Automated 3D Printing Market Revenues & Volume, By Software, 2021-2031F |
6.3 Automated 3D Printing Market Revenues & Volume, By Services, 2021-2031F |
7 Automated 3D Printing Market Overview, By Process |
7.1 Automated 3D Printing Market Revenues & Volume, By Material Handling, 2021-2031F |
7.2 Automated 3D Printing Market Revenues & Volume, By Automated Production, 2021-2031F |
7.3 Automated 3D Printing Market Revenues & Volume, By Part Handling, 2021-2031F |
7.4 Automated 3D Printing Market Revenues & Volume, By Post Handling, 2021-2031F |
7.5 Automated 3D Printing Market Revenues & Volume, By Multiprocessing, 2021-2031F |
8 Automated 3D Printing Market Overview, By End Users |
8.1 Automated 3D Printing Market Revenues & Volume, By Defense, 2021-2031F |
8.2 Automated 3D Printing Market Revenues & Volume, By Healthcare, 2021-2031F |
8.3 Automated 3D Printing Market Revenues & Volume, By Industrial Manufacturing, 2021-2031F |
8.4 Automated 3D Printing Market Revenues & Volume, By Automation, 2021-2031F |
8.5 Automated 3D Printing Market Revenues & Volume, By Consumer Products, 2021-2031F |
8.6 Automated 3D Printing Market Revenues & Volume, By Energy, 2021-2031F |
8.7 Automated 3D Printing Market Revenues & Volume, By Others, 2021-2031F |
9 North America Automated 3D Printing Market Overview |
9.1 North America Automated 3D Printing Market Revenues & Volume, 2021-2031F |
9.2 North America Automated 3D Printing Market Revenues & Volume, By Offering, 2021-2031F |
9.3 North America Automated 3D Printing Market Revenues & Volume, By Process, 2021-2031F |
9.4 North America Automated 3D Printing Market Revenues & Volume, By End User, 2021-2031F |
9.5 North America Automated 3D Printing Market Revenues & Volume, By Countries, 2021-2031F |
10 Latin America Automated 3D Printing Market Overview |
10.1 Latin America Automated 3D Printing Market Revenues & Volume, 2021-2031F |
10.2 Latin America Automated 3D Printing Market Revenues & Volume, By Offering, 2021-2031F |
10.3 Latin America Automated 3D Printing Market Revenues & Volume, By Process, 2021-2031F |
10.4 Latin America Automated 3D Printing Market Revenues & Volume, By End User, 2021-2031F |
10.5 Latin America Automated 3D Printing Market Revenues & Volume, By Countries, 2021-2031F |
11 Europe Automated 3D Printing Market Overview |
11.1 Europe Automated 3D Printing Market Revenues & Volume, 2021-2031F |
11.2 Europe Automated 3D Printing Market Revenues & Volume, By Offering, 2021-2031F |
11.3 Europe Automated 3D Printing Market Revenues & Volume, By Process, 2021-2031F |
11.4 Europe Automated 3D Printing Market Revenues & Volume, By End User, 2021-2031F |
11.5 Europe Automated 3D Printing Market Revenues & Volume, By Countries, 2021-2031F |
12 Asia Pacific Automated 3D Printing Market Overview |
12.1 Asia Pacific Automated 3D Printing Market Revenues & Volume, 2021-2031F |
12.2 Asia Pacific Automated 3D Printing Market Revenues & Volume, By Offering, 2021-2031F |
12.3 Asia Pacific Automated 3D Printing Market Revenues & Volume, By Process, 2021-2031F |
12.4 Asia Pacific Automated 3D Printing Market Revenues & Volume, By End User, 2021-2031F |
12.5 Asia Pacific Automated 3D Printing Market Revenues & Volume, By Countries, 2021-2031F |
13 ROW Automated 3D Printing Market Overview |
13.1 ROW Automated 3D Printing Market Revenues & Volume, 2021-2031F |
14 Automated 3D Printing Market Opportunity Assessment |
14.1 Automated 3D Printing Market Opportunity Assessment, By Offering, 2031F |
14.2 Automated 3D Printing Market Opportunity Assessment, By Process, 2031F |
14.3 Automated 3D Printing Market Opportunity Assessment, By End User, 2031F |
14.4 Automated 3D Printing Market Opportunity Assessment, By Regions, 2031F |
15 Automated 3D Printing Market Competitive Landscape |
15.1 Automated 3D Printing Market Revenue Share, By Companies, 2024 |
15.1.1 North America Automated 3D Printing Market Revenue Share, By Companies, 2024 |
15.1.2 Latin America Automated 3D Printing Market Revenue Share, By Companies, 2024 |
15.1.3 Europe Automated 3D Printing Market Revenue Share, By Companies, 2024 |
15.1.4 Asia-Pacific Automated 3D Printing Market Revenue Share, By Companies, 2024 |
15.2 Automated 3D Printing Market Competitive Benchmarking, By Operating Parameters |
16 Company Profiles |
17 Strategic Recommendations |
18 Disclaimer |