As per Intent Market Research, the 3D Scanner Market was valued at USD 3.4 billion in 2023 and will surpass USD 8.5 billion by 2030; growing at a CAGR of 14.1% during 2024 - 2030.
The global 3D scanner market is experiencing robust growth, driven by advancements in 3D technology and increasing applications across various industries. 3D scanners capture the precise shape and size of objects in real time, allowing for accurate digitization, which has transformed industries like automotive, aerospace, healthcare, and manufacturing. These scanners are used in a variety of fields, from quality control and inspection to reverse engineering and medical imaging.The growth is propelled by increasing demand for high-precision scanning technologies in emerging markets, as well as by technological advancements that are making 3D scanning more accessible and efficient.
Hardware Segment is Largest Owing to Increasing Industrial Adoption
The hardware segment of the 3D scanner market dominates in terms of revenue and market share. Hardware includes various 3D scanner types, such as laser scanners, structured light scanners, and optical scanners, which are the backbone of 3D scanning technology. This segment's prominence is driven by the growing need for high-quality, precise scanning equipment in industries like automotive, aerospace, and healthcare. Manufacturers in these sectors rely heavily on 3D scanners for reverse engineering, product development, and quality control.
Within the hardware segment, laser scanners represent the largest subsegment, accounting for the majority of the market share. The precision and reliability of laser scanning technology have made it the go-to choice for industrial applications. Laser scanners provide excellent accuracy and range, making them indispensable for large-scale applications, such as construction, architecture, and shipbuilding, where capturing large objects with high precision is critical.
Automated 3D Scanning Solutions Driving Software Segment Growth
The software segment is witnessing rapid growth, driven by the increasing demand for automated 3D scanning solutions. As industries move toward automation and Industry 4.0, the integration of 3D scanning technologies into automated production lines has become a major trend. The software used in 3D scanning helps to process the captured data, perform measurements, and generate 3D models for further use in simulations or production.
The automated 3D scanning software subsegment is the fastest-growing, driven by the need for faster and more efficient scanning processes, particularly in sectors such as automotive and aerospace. These industries require real-time data processing and analysis for quality control and inspection, and automated scanning software enables seamless integration of 3D scanners into production workflows. As automation continues to evolve, this subsegment is expected to witness accelerated growth, supported by advancements in artificial intelligence (AI) and machine learning (ML) algorithms.
Handheld 3D Scanners Lead the Product Type Segment
In terms of product types, handheld 3D scanners are the most popular, accounting for the largest market share. These portable devices are highly versatile and can be used across various applications, from industrial design and manufacturing to healthcare and cultural preservation. Their portability and ease of use make them ideal for scanning objects in hard-to-reach places or for on-site inspections.
Handheld scanners are particularly popular in healthcare and heritage preservation. In healthcare, they are used to create digital models of patients for prosthetics, dental applications, and reconstructive surgeries. In heritage preservation, handheld 3D scanners help in digitizing historical artifacts and cultural heritage sites, preserving them in high detail for future generations.
Reverse Engineering Leads Application Segment
The reverse engineering subsegment dominates the application segment of the 3D scanner market. Reverse engineering involves using 3D scanning technology to recreate the design and manufacturing process of an object, often for product development or to improve upon existing designs. This process is particularly critical in the automotive and aerospace industries, where companies use 3D scanners to analyze parts and components for modifications or to generate CAD models for prototyping.
Reverse engineering is essential for businesses that need to develop new products quickly, reduce production costs, or adapt to changing industry standards. With the increasing demand for customization and shorter product life cycles, the importance of reverse engineering in manufacturing is expected to grow significantly in the coming years.
Industrial Manufacturing Segment Grows Fastest with High Demand for Precision
The industrial manufacturing segment is the fastest-growing segment by end-user, as manufacturers across the globe adopt 3D scanning technology for quality control, inspection, and production processes. With the advent of smart factories and the rise of digital twins, the role of 3D scanning in manufacturing has expanded dramatically.
3D scanners allow manufacturers to conduct precise measurements and inspections of complex parts and components. They help ensure that products meet stringent quality standards, reducing errors and improving efficiency. In the era of Industry 4.0, manufacturers are increasingly adopting automated 3D scanning systems that are integrated directly into production lines, further driving growth in this segment.
Asia-Pacific Region to Lead Market Growth
The Asia-Pacific region is projected to be the fastest-growing region in the 3D scanner market, driven by rapid industrialization, technological advancements, and the increasing adoption of 3D scanning technology in countries like China, Japan, and South Korea. The region's manufacturing sector, particularly in the automotive, electronics, and aerospace industries, is investing heavily in 3D scanning technology to enhance product development and quality control processes.
China, in particular, is emerging as a major hub for 3D scanning technology, with numerous local players entering the market and increasing competition. The country's robust manufacturing base and its emphasis on adopting advanced technologies, such as 3D printing and scanning, position it as a key driver of growth in the Asia-Pacific region.
Competitive Landscape and Key Players
The global 3D scanner market is highly competitive, with key players continuously investing in research and development to improve their product offerings. Leading companies include Hexagon AB, FARO Technologies, Creaform, Nikon Metrology, and Trimble Inc., all of which are known for their innovations in 3D scanning technology.
The competitive landscape is characterized by mergers and acquisitions, strategic partnerships, and technological innovations. As industries increasingly demand high-precision and automated 3D scanning solutions, companies are focusing on developing AI-driven and automated scanning systems to stay competitive. Furthermore, regional players, especially in the Asia-Pacific region, are expanding their market presence, contributing to the overall competitiveness of the market.
Report Objectives:
The report will help you answer some of the most critical questions in the 3D Scanner Market. A few of them are as follows:
- What are the key drivers, restraints, opportunities, and challenges influencing the market growth?
- What are the prevailing technology trends in the 3D Scanner Market?
- What is the size of the 3D Scanner Market based on segments, sub-segments, and regions?
- What is the size of different market segments across key regions: North America, Europe, Asia-Pacific, Latin America, Middle East & Africa?
- What are the market opportunities for stakeholders after analyzing key market trends?
- Who are the leading market players and what are their market share and core competencies?
- What is the degree of competition in the market and what are the key growth strategies adopted by leading players?
- What is the competitive landscape of the market, including market share analysis, revenue analysis, and a ranking of key players?
Report Scope:
|
Report Features |
Description |
|
Market Size (2023) |
USD 3.4 billion |
|
Forecasted Value (2030) |
USD 8.5 billion |
|
CAGR (2024 – 2030) |
14.1% |
|
Base Year for Estimation |
2023 |
|
Historic Year |
2022 |
|
Forecast Period |
2024 – 2030 |
|
Report Coverage |
Market Forecast, Market Dynamics, Competitive Landscape, Recent Developments |
|
Segments Covered |
3D Scanner Market By Type (Laser 3D Scanners, Structured Light 3D Scanners, Optical 3D Scanners), By Range (Short Range, Medium Range, Long Range), By Technology (Laser Triangulation, Time-of-Flight, Pattern Fringe Triangulation, Photogrammetry), By Application (Reverse Engineering, Quality Control & Inspection, Virtual Simulation, 3D Modeling), By End-User (Automotive, Aerospace & Defense, Healthcare, Architecture & Construction, Consumer Products, Industrial Manufacturing) |
|
Regional Analysis |
North America (US, Canada, Mexico), Europe (Germany, France, UK, Italy, Spain, and Rest of Europe), Asia-Pacific (China, Japan, South Korea, Australia, India, and Rest of Asia-Pacific), Latin America (Brazil, Argentina, and Rest of Latin America), Middle East & Africa (Saudi Arabia, UAE, Rest of Middle East & Africa) |
|
Customization Scope |
Customization for segments, region/country-level will be provided. Moreover, additional customization can be done based on the requirements |
|
1. Introduction |
|
1.1. Market Definition |
|
1.2. Scope of the Study |
|
1.3. Research Assumptions |
|
1.4. Study Limitations |
|
2. Research Methodology |
|
2.1. Research Approach |
|
2.1.1. Top-Down Method |
|
2.1.2. Bottom-Up Method |
|
2.1.3. Factor Impact Analysis |
|
2.2. Insights & Data Collection Process |
|
2.2.1. Secondary Research |
|
2.2.2. Primary Research |
|
2.3. Data Mining Process |
|
2.3.1. Data Analysis |
|
2.3.2. Data Validation and Revalidation |
|
2.3.3. Data Triangulation |
|
3. Executive Summary |
|
3.1. Major Markets & Segments |
|
3.2. Highest Growing Regions and Respective Countries |
|
3.3. Impact of Growth Drivers & Inhibitors |
|
3.4. Regulatory Overview by Country |
|
4. 3D Scanner Market, by Type (Market Size & Forecast: USD Million, 2022 – 2030) |
|
4.1. Laser 3D Scanners |
|
4.2. Structured Light 3D Scanners |
|
4.3. Optical 3D Scanners |
|
4.4. Others |
|
5. 3D Scanner Market, by Range (Market Size & Forecast: USD Million, 2022 – 2030) |
|
5.1. Short Range |
|
5.2. Medium Range |
|
5.3. Long Range |
|
6. 3D Scanner Market, by Technology (Market Size & Forecast: USD Million, 2022 – 2030) |
|
6.1. Laser Triangulation |
|
6.2. Time-of-Flight |
|
6.3. Pattern Fringe Triangulation |
|
6.4. Photogrammetry |
|
6.5. Others |
|
7. 3D Scanner Market, by Application (Market Size & Forecast: USD Million, 2022 – 2030) |
|
7.1. Reverse Engineering |
|
7.2. Quality Control & Inspection |
|
7.3. Virtual Simulation |
|
7.4. 3D Modeling |
|
7.5. Others |
|
8. 3D Scanner Market, by End-User (Market Size & Forecast: USD Million, 2022 – 2030) |
|
8.1. Automotive |
|
8.2. Aerospace & Defense |
|
8.3. Healthcare |
|
8.4. Architecture & Construction |
|
8.5. Consumer Products |
|
8.6. Industrial Manufacturing |
|
8.7. Others |
|
9. Regional Analysis (Market Size & Forecast: USD Million, 2022 – 2030) |
|
9.1. Regional Overview |
|
9.2. North America |
|
9.2.1. Regional Trends & Growth Drivers |
|
9.2.2. Barriers & Challenges |
|
9.2.3. Opportunities |
|
9.2.4. Factor Impact Analysis |
|
9.2.5. Technology Trends |
|
9.2.6. North America 3D Scanner Market, by Type |
|
9.2.7. North America 3D Scanner Market, by Range |
|
9.2.8. North America 3D Scanner Market, by Technology |
|
9.2.9. North America 3D Scanner Market, by Application |
|
9.2.10. North America 3D Scanner Market, by End-User |
|
9.2.11. By Country |
|
9.2.11.1. US |
|
9.2.11.1.1. US 3D Scanner Market, by Type |
|
9.2.11.1.2. US 3D Scanner Market, by Range |
|
9.2.11.1.3. US 3D Scanner Market, by Technology |
|
9.2.11.1.4. US 3D Scanner Market, by Application |
|
9.2.11.1.5. US 3D Scanner Market, by End-User |
|
9.2.11.2. Canada |
|
9.2.11.3. Mexico |
|
*Similar segmentation will be provided for each region and country |
|
9.3. Europe |
|
9.4. Asia-Pacific |
|
9.5. Latin America |
|
9.6. Middle East & Africa |
|
10. Competitive Landscape |
|
10.1. Overview of the Key Players |
|
10.2. Competitive Ecosystem |
|
10.2.1. Level of Fragmentation |
|
10.2.2. Market Consolidation |
|
10.2.3. Product Innovation |
|
10.3. Company Share Analysis |
|
10.4. Company Benchmarking Matrix |
|
10.4.1. Strategic Overview |
|
10.4.2. Product Innovations |
|
10.5. Start-up Ecosystem |
|
10.6. Strategic Competitive Insights/ Customer Imperatives |
|
10.7. ESG Matrix/ Sustainability Matrix |
|
10.8. Manufacturing Network |
|
10.8.1. Locations |
|
10.8.2. Supply Chain and Logistics |
|
10.8.3. Product Flexibility/Customization |
|
10.8.4. Digital Transformation and Connectivity |
|
10.8.5. Environmental and Regulatory Compliance |
|
10.9. Technology Readiness Level Matrix |
|
10.10. Technology Maturity Curve |
|
10.11. Buying Criteria |
|
11. Company Profiles |
|
11.1. 3D Systems |
|
11.1.1. Company Overview |
|
11.1.2. Company Financials |
|
11.1.3. Product/Service Portfolio |
|
11.1.4. Recent Developments |
|
11.1.5. IMR Analysis |
|
*Similar information will be provided for other companies |
|
11.2. Ametek |
|
11.3. Artec 3D |
|
11.4. FARO Technologies |
|
11.5. Hexagon |
|
11.6. Nikon |
|
11.7. Perceptron |
|
11.8. Topcon Corporation |
|
11.9. Trimble |
|
11.10. ZEISS Group |
|
12. Appendix |
A comprehensive market research approach was employed to gather and analyze data on the 3D Scanner Market. In the process, the analysis was also done to analyze the parent market and relevant adjacencies to measure the impact of them on the 3D Scanner Market. The research methodology encompassed both secondary and primary research techniques, ensuring the accuracy and credibility of the findings.
.jpg)
Secondary Research
Secondary research involved a thorough review of pertinent industry reports, journals, articles, and publications. Additionally, annual reports, press releases, and investor presentations of industry players were scrutinized to gain insights into their market positioning and strategies.
Primary Research
Primary research involved conducting in-depth interviews with industry experts, stakeholders, and market participants across the 3D Scanner ecosystem. The primary research objectives included:
- Validating findings and assumptions derived from secondary research
- Gathering qualitative and quantitative data on market trends, drivers, and challenges
- Understanding the demand-side dynamics, encompassing end-users, component manufacturers, facility providers, and service providers
- Assessing the supply-side landscape, including technological advancements and recent developments
Market Size Assessment
A combination of top-down and bottom-up approaches was utilized to analyze the overall size of the 3D Scanner Market. These methods were also employed to assess the size of various subsegments within the market. The market size assessment methodology encompassed the following steps:
- Identification of key industry players and relevant revenues through extensive secondary research
- Determination of the industry's supply chain and market size, in terms of value, through primary and secondary research processes
- Calculation of percentage shares, splits, and breakdowns using secondary sources and verification through primary sources
.jpg)
Data Triangulation
To ensure the accuracy and reliability of the market size, data triangulation was implemented. This involved cross-referencing data from various sources, including demand and supply side factors, market trends, and expert opinions. Additionally, top-down and bottom-up approaches were employed to validate the market size assessment.
NA