A quick peek into the report
Table of Contents
1.1 Industry Outlook
1.1.1 Robotic Integration for the Manufacturing Market: Overview
1.1.1.1 Vision Systems
1.1.1.2 Machine Control and Integration
1.1.1.3 Material Handling and Motion Control
1.1.1.4 Platforms, Systems, and Architecture
1.1.2 Transition from Industry 4.0 to Industry 5.0
1.1.3 Trends Enabling the Robotics Industry
1.1.3.1 Internet of Robotic Things (IoRT)
1.1.3.2 5G-Enabled Smart Factory
1.1.3.3 Autonomous Mobile Robots
1.1.3.4 Collaborative Robot (Cobot) Integration with Humans
1.1.4 Robotic Efficiency and Accuracy Analysis
1.1.5 Traditional and Non-Traditional Use Cases in Key Industries
1.1.6 Standards and Regulations
1.1.7 Startups and Investment Landscape
1.2 Business Dynamics
1.2.1 Business Drivers
1.2.1.1 Increase in the Role of AI and ML in Robotics Technology
1.2.1.2 Increase in the Prevalence of Robotic Palletizing
1.2.2 Business Challenges
1.2.2.1 Lack of Expertise in Robotics Integration
1.2.3 Business Opportunities
1.2.3.1 Rise of Robots-as-a-Service (RaaS) in Manufacturing
2.1 U.S. Robotics Integration for the Manufacturing Market (by Application)
2.1.1 Market Overview
2.1.1.1 Demand Analysis of U.S. Robotics Integration for the Manufacturing Market (by Application), Value and Volume
2.1.2 Aviation
2.1.2.1 Trend Analysis
2.1.3 SpaceTech
2.1.3.1 Trend Analysis
2.1.4 Automotive
2.1.4.1 Trend Analysis
2.1.5 Consumer Electronics
2.1.5.1 Trend Analysis
2.1.6 Semiconductor
2.1.6.1 Trend Analysis
2.1.7 Renewable Energy and Power
2.1.7.1 CleanTech
2.1.7.2 Nuclear
2.1.7.3 BlueTech
2.1.7.4 Trend Analysis
2.1.8 FoodTech
2.1.8.1 Trend Analysis
2.1.9 Warehousing
2.1.9.1 Trend Analysis
2.1.10 HealthTech and MedTech
2.1.10.1 Trend Analysis
3.1 U.S. Robotics Integration for the Manufacturing Market (by Type)
3.1.1 Market Overview
3.1.1.1 Demand Analysis of U.S. Robotics Integration for the Manufacturing Market (by Type), Value and Volume
3.1.2 Autonomous Mobile Robots (AMRs)
3.1.3 Automated Guided Vehicles (AGVs)
3.1.4 Collaborative Robots (Cobots)
3.1.5 Other
4.1 Competitive Benchmarking
4.2 Company Profiles
4.2.1 ACRO Automation Systems, Inc.
4.2.1.1 Company Overview
4.2.1.1.1 Role of ACRO Automation Systems, Inc. in the U.S. Robotics Integration for the Manufacturing Market
4.2.1.2 Analyst View
4.2.2 Andrews Cooper
4.2.2.1 Company Overview
4.2.2.1.1 Role of Andrews Cooper in the U.S. Robotics Integration for the Manufacturing Market
4.2.2.2 Analyst View
4.2.3 Bastian Solutions, LLC
4.2.3.1 Company Overview
4.2.3.1.1 Role of Bastian Solutions, LLC in the U.S. Robotics Integration for the Manufacturing Market
4.2.3.1.2 Product Portfolio
4.2.3.2 Business Strategies
4.2.3.2.1 Product Developments and Fundings
4.2.3.3 Corporate Strategies
4.2.3.3.1 Partnerships, Collaborations, Contracts, and Agreements
4.2.3.4 Analyst View
4.2.4 Cleveland Automation Systems
4.2.4.1 Company Overview
4.2.4.1.1 Role of Cleveland Automation Systems in the U.S. Robotics Integration for the Manufacturing Market
4.2.4.2 Analyst View
4.2.5 Dynamic Automation
4.2.5.1 Company Overview
4.2.5.1.1 Role of Dynamic Automation in the U.S. Robotics Integration for the Manufacturing Market
4.2.5.2 Analyst View
4.2.6 enVista, LLC.
4.2.6.1 Company Overview
4.2.6.1.1 Role of enVista, LLC. in the U.S. Robotics Integration for the Manufacturing Market
4.2.6.2 Analyst View
4.2.7 KC Robotics
4.2.7.1 Company Overview
4.2.7.1.1 Role of KC Robotics in the U.S. Robotics Integration for the Manufacturing Market
4.2.7.2 Analyst View
4.2.8 Productivity Inc.
4.2.8.1 Company Overview
4.2.8.1.1 Role of Productivity Inc. in the U.S. Robotics Integration for the Manufacturing Market
4.2.8.1.2 Product Portfolio
4.2.8.2 Analyst View
4.2.9 Remtec Automation, LLC.
4.2.9.1 Company Overview
4.2.9.1.1 Role of Remtec Automation, LLC. in the U.S. Robotics Integration for the Manufacturing Market
4.2.9.2 Analyst View
4.2.10 Steven Douglas Corp.
4.2.10.1 Company Overview
4.2.10.1.1 Role of Steven Douglas Corp. in the U.S. Robotics Integration for the Manufacturing Market
4.2.10.2 Analyst View
4.2.11 Other Key Market Participants
4.2.11.1 Jabil Inc.
4.2.11.1.1 Company Overview
4.2.11.2 JR Automation
4.2.11.2.1 Company Overview
5.1 Growth Opportunities
5.1.1 Growth Opportunity 1: Growing Demand from Automotive Market
5.1.1.1 Recommendation
5.1.2 Growth Opportunity 2: Growing Demand for Warehouse Automation
5.1.2.1 Recommendation
6.1 Factors for Data Prediction and Modeling
Table 1: Industry 4.0 vs. Industry 5.0
Table 2: Level of Collaboration Between Humans and Robots
Table 3: Funding and Investment Comparisons, July 2021-December 2023
Table 4: U.S. Robotics Integration for the Manufacturing Market (by Application), $Million, 2023-2029
Table 5: U.S. Robotics Integration for the Manufacturing Market (by Application), Units, 2023-2029
Table 6: U.S. Robotics Integration for the Manufacturing Market (by Type), $Million, 2023-2029
Table 7: U.S. Robotics Integration for the Manufacturing Market (by Type), Units, 2023-2029
Table 8: Bastian Solutions, LLC: Product Portfolio
Table 9: Bastian Solutions, LLC: Product Developments and Fundings
Table 10: Bastian Solutions, LLC: Partnerships, Collaborations, Contracts, and Agreements
Table 11: Productivity, Inc.: Product Portfolio
Figure 1: U.S. Robotics Integration for the Manufacturing Market, $Billion, 2023-2029
Figure 2: U.S. Robotics Integration for the Manufacturing Market, Units, 2023 to 2029
Figure 3: U.S. Robotics Integration for the Manufacturing Market (by Application), $Billion, 2024-2029
Figure 4: U.S. Robotics Integration for the Manufacturing Market (by Application), Units, 2024-2029
Figure 5: U.S. Robotics Integration for the Manufacturing Market (by Type), $Billion, 2024 to 2029
Figure 6: U.S. Robotics Integration for the Manufacturing Market (by Type), Units, 2024-2029
Figure 7: U.S. Robotics Integration for the Manufacturing Market Coverage
Figure 8: U.S. Robotics Integration for the Manufacturing Market, Business Dynamics
Figure 9: U.S. Robotics Integration for the Manufacturing Market (by Application)
Figure 10: U.S. Robotics Integration for the Manufacturing Market (by Type)
Figure 11: U.S. Robotics Integration for the Manufacturing Market: Competitive Benchmarking, 2023
Figure 12: Research Methodology
Figure 13: Top-Down and Bottom-Up Approach
Figure 14: Assumptions and Limitations
U.S. Robotics Integration for the Manufacturing Market Report Coverage
U.S. Robotics Integration for the Manufacturing Market |
|||
Base Year |
2023 |
Market Size in 2023 |
$3.94 Billion |
Forecast Period |
2024-2029 |
Value Projection and Estimation by 2029 |
$7.48 Billion |
CAGR During Forecast Period |
11.69 % |
Number of Pages |
97 |
Number of Tables | 11 |
Number of Figures |
14 |
Key Market Players and Competition Synopsis
The companies that are profiled have been selected based on thorough secondary research, which includes analyzing company coverage, product portfolio, market penetration, and insights gathered from primary experts.
The U.S. robotics integration for the manufacturing market comprises key players who have established themselves thoroughly and have the proper understanding of the market, accompanied by start-ups looking forward to establishing themselves in this highly competitive market. In 2022, the U.S. robotics integration for the manufacturing market was dominated by established players, accounting for 90% of the market share, whereas start-ups managed to capture 10% of the market. With the growing need for advanced diagnostic tools and quality assurance in various industries, the U.S. robotics integration for the manufacturing market is expected to see significant expansion. This growth is driven by expanding applications of robotics across sectors, including automotive, electronics, and healthcare, and the rising demand for precision, efficiency, and safety in production lines.
Some prominent names established in this market are:
• Andrews Cooper
• Steven Douglas Corp.
• Cleveland Automation Systems
• Bastian Solutions, LLC
• KC Robotics
• enVista, LLC.
• Productivity Inc.
• Remtec Automation, LLC.
• Dynamic Automation
• ACRO Automation Systems, Inc.
How can this report add value to an organization?
Product/Innovation Strategy: The product segment helps the reader understand the different types of products available for deployment and their potential globally. Moreover, the study provides the reader with a detailed understanding of the U.S. robotics integration for the manufacturing market by applications such as aviation, SpaceTech, automotive, consumer electronics, semiconductor, renewable energy and power, FoodTech, warehousing, and HealthTech and MedTech and on the basis of type, the market has been segmented into autonomous mobile robots (AMRs), automated guided vehicles (AGVs), collaborative robots (cobots), and others.
Growth/Marketing Strategy: The U.S. robotics integration for the manufacturing market has seen development by robot manufacturers and robot integrators operating in the market, such as business expansion, partnership, collaboration, and joint venture. The favored strategy for the companies has been the launch of new products to strengthen their position in the U.S. robotics integration for the manufacturing market. For instance, in December 2023, Brightpick, a warehouse automation solutions provider, revealed details about its advanced machine vision and AI technologies crucial for its Brightpick Autopicker robots. These technologies enable tasks such as scanning totes, creating 3D models, and determining optimal picking angles. The Brightpick Intuition software orchestrates the entire robot fleet for maximum throughput in e-commerce and e-grocery warehouses. The Autopicker, an autonomous mobile robot, uses a two-axis SCARA robotic arm with suction cups driven by AI and machine vision, ensuring picking accuracy for a diverse range of products.
Competitive Strategy: Key players in the U.S. robotics integration for the manufacturing market analyzed and profiled in the study involve robot manufacturers and robot integrators. Moreover, a detailed competitive benchmarking of the players operating in the U.S. robotics integration for the manufacturing market has been done to help the reader understand how players stack against each other, presenting a clear market landscape. Additionally, comprehensive competitive strategies such as partnerships, agreements, and collaborations will aid the reader in understanding the untapped revenue pockets in the market.\
Methodology: The research methodology design adopted for this specific study includes a mix of data collected from primary and secondary data sources. Both primary resources (key players, market leaders, and in-house experts) and secondary research (a host of paid and unpaid databases), along with analytical tools, have been employed to build the predictive and forecast models.
Data and validation have been taken into consideration from both primary sources as well as secondary sources.
Key Considerations and Assumptions in Market Engineering and Validation
• Detailed secondary research has been done to ensure maximum coverage of manufacturers/suppliers operational in a country.
• Exact revenue information, up to a certain extent, has been extracted for each company from secondary sources and databases. Revenues specific to product/application/technology were then estimated based on fact-based proxy indicators as well as primary inputs.
• Based on the classification, the average selling price (ASP) has been calculated using the weighted average method.
• The currency conversion rate has been taken from the historical exchange rate of Oanda and/or other relevant websites.
• Any economic downturn in the future has not been taken into consideration for the market estimation and forecast.
• The base currency considered for the market analysis is US$. Currencies other than the US$ have been converted to the US$ for all statistical calculations, considering the average conversion rate for that particular year.
• The term “product” in this document may refer to “service” or “technology” as and where relevant.
• The term “manufacturers/suppliers” may refer to “service providers” or “technology providers” as and where relevant.
Primary Research
The primary sources involve industry experts from the robotic industry, including robot manufacturers and robotic integration solution providers. Respondents such as CEOs, vice presidents, marketing directors, and technology and innovation directors have been interviewed to obtain and verify both qualitative and quantitative aspects of this research study.
Secondary Research
This study involves the usage of extensive secondary research, company websites, directories, and annual reports. It also makes use of databases, such as Businessweek and others, to collect effective and useful information for a market-oriented, technical, commercial, and extensive study of the global market. In addition to the data sources, the study has been undertaken with the help of other data sources and websites.
Secondary research was done to obtain critical information about the industry’s value chain, the market’s monetary chain, revenue models, the total pool of key players, and the current and potential use cases and applications.
Introduction of U.S. Robotics Integration for the Manufacturing
Robotics integration in the U.S. signifies a transformative phase in the industrial and technological landscapes, driven by advancements in automation, artificial intelligence, and machine learning. The integration of robotics is reshaping various sectors, including manufacturing, healthcare, and service industries, by enhancing efficiency, productivity, and safety. This transition is supported by a robust ecosystem involving policymakers, educational institutions, manufacturers of robotic systems, and end users, fostering a conducive environment for innovation and growth.
The U.S. government, recognizing the strategic importance of robotics, has initiated several programs and investments to accelerate research and development, workforce training, and ethical deployment of robotics. For instance, the Advanced Robotics for Manufacturing (ARM) Institute reflects a concerted effort to fortify the country's global leadership in this domain. Moreover, collaboration between universities and industry is pivotal in pushing the boundaries of robotics technology, ensuring a steady flow of skilled labor, and addressing the challenges of integration.
Market Introduction
The integration of robotics in the U.S. manufacturing sector marks a significant paradigm shift toward Industry 5.0, which emphasizes a human-centric approach, increased resilience, and focus on sustainability, shifting from a sole focus on efficiency and productivity to a broader vision of industry contributing to society's well-being. Industry 5.0 is value-driven, combining technology with a focus on people and environment. The manufacturing market is increasingly embracing robotics to address challenges such as labor shortages, need for precision and consistency in production, and imperative for sustainable practices. Robotics integration is pivotal in automating repetitive and hazardous tasks, leading to enhanced efficiency and reduced downtime. Advanced robotic systems equipped with sensors and AI capabilities are enabling predictive maintenance, quality control, and customized production, aligning with the just-in-time manufacturing model.
Furthermore, the rise of cobots is a notable trend. Cobots are designed to work alongside humans, enhancing safety and productivity. Cobots are being increasingly adopted for tasks that require precision and flexibility, proving to be cost-effective for small- and medium-sized enterprises. Robotics offers solutions for material handling, packaging, and logistics. Automated guided vehicles (AGVs) and autonomous mobile robots (AMRs) are revolutionizing warehouse operations, ensuring timely and accurate fulfillment of orders.
Additionally, the U.S. government is actively involved in shaping policies to ensure a balanced approach to robotics integration, addressing concerns related to labor displacement, privacy, and ethical considerations. Collaboration between regulatory bodies and industry stakeholders is vital to establishing standards and best practices.
Industrial Impact
The integration of robotics in the U.S. manufacturing market is profoundly reshaping the industrial landscape, heralding a new era of productivity, innovation, and competitiveness. Robotics integration fundamentally alters production processes, enabling higher throughput, precision, and consistency. Automated production lines powered by robotics minimize human error, reduce waste, and ensure optimal utilization of resources. This efficiency is critical in sectors where precision and repeatability are paramount, such as electronics, automotive, and pharmaceuticals.
Moreover, the integration of robotics in the U.S. manufacturing market is a multi-dimensional paradigm shift, influencing not just the production processes but also the economic, educational, and social fabrics of the industrial sector. This transformation, while replete with challenges, presents immense opportunities for growth, innovation, and sustainable development, asserting the pivotal role of robotics in shaping the future of U.S. manufacturing.
Market Segmentation:
Segmentation 1: by Application
• Aviation
• SpaceTech
• Automotive
• Consumer Electronics
• Semiconductor
• Renewable Energy and Power
• FoodTech
• Warehousing
• HealthTech and MedTech
Automotive Segment to Dominate the U.S. Robotics Integration for the Manufacturing Market (by Application)
The automotive segments in the U.S. robotics integration for the manufacturing market is leading the market, principally attributed to its intrinsic need for high-volume, precision manufacturing, which aligns seamlessly with the capabilities of robotic systems. In the automotive industry, the rapid evolution of connectivity and technology, propelled by advancements in artificial intelligence (AI), advanced driver assistance systems (ADAS), and expanding vehicle-to-everything (V2X) infrastructure, is steering the sector toward autonomous driving. The integration of robotics in automotive manufacturing is instrumental in this transformation, offering precision and quality in the production of sophisticated components, scalability to meet the surging demand, and adaptability to rapidly evolving technology. Robotics in manufacturing underpins the complex assembly processes required for modern vehicles, ensuring that the automotive industry can efficiently produce vehicles equipped with the latest AI, ADAS, and V2X systems, thereby shaping the future of automotive technology and mobility.
Segmentation 2: by Type
• Autonomous Mobile Robots (AMRs)
• Automated Guided Vehicles (AGVs)
• Collaborative Robots (Cobots)
• Others
Recent Developments in the U.S. Robotics Integration for the Manufacturing Market
• In January 2024, Teledyne FLIR IIS committed to revolutionizing machine vision with its latest Spinnaker 4 release, a GeniCam3 API library, which sets a new standard for machine vision developers with unparalleled performance and reliability. Tested under extreme conditions, including continuous operation with 40 GigE cameras for multiple days, it maintains flawless image capture and efficient processing even at over 90% CPU usage. This advancement underscores Teledyne FLIR IIS's dedication to delivering top-tier imaging technologies, ensuring reliability without compromising performance in challenging industrial environments.
• In July 2023, Kivnon, a global provider of autonomous mobile robots (AMRs) and automated guided vehicles (AGVs), announced a partnership with TAP, a prominent industrial solutions provider, for the distribution of Kivnon AGVs and AMRs. Kivnon specializes in designing, manufacturing, and implementing AGVs and AMRs across various industries, including automotive, food, aerospace, and retail. Its product range includes small AGVs for lab use, mouse AGV platforms for pallet handling, tractor AGVs for cart pulling, and self-driving forklifts. This collaboration with TAP aims to capitalize on the growing interest in AGVs and AMRs driven by Industry 4.0's digital transformation.
• In February 2023, ABB introduced the SWIFTI CRB 1300 industrial collaborative robot, featuring an enhanced load-handling capacity of up to 11kg. The robot is designed to address the intersection of industrial and collaborative robots, offering features such as palletizing and pick-and-place functionalities. With a reported top speed of 6.2m/s, the solution provides payload options ranging from 7kg to 11kg and reaches from 0.9 to 1.4 meters. Notably, it can handle higher payload tasks such as screwdriving. ABB's commitment to durability is evident in the robot's additional protection against dust and moisture, which achieved an IP67 rating and made it suitable for demanding applications such as machine tending.
Demand – Drivers, Challenges, and Opportunities
Market Drivers: Increase in the Role of AI and ML in Robotics Technology
The ongoing evolution of robotic technology, enhanced by artificial intelligence (AI) and machine learning (ML), is instrumental in enabling robots to tackle more intricate tasks and swiftly adapt to dynamic environments. This technological progress is a driving force behind the escalating demand for robotics integration for the manufacturing industry.
Market Challenges: Lack of Expertise in Robotics Integration
Securing competent support staff well-versed in the intricacies of industrial robots is crucial for companies aiming for excellence in robotics system integration. However, the scarcity of candidates with the requisite skills poses a significant challenge. With industrial robots evolving in complexity regarding technicalities, features, and products, companies are grappling with the dual challenge of finding and equipping their staff with the necessary capabilities to meet customer demands.
Market Opportunities: Rise of Robots-as-a-Service in Manufacturing
As manufacturers seek agile, efficient, and cost-effective solutions, robots-as-a-service emerges as a transformative opportunity in the robotics integration market. The advent of robots-as-a-service (RaaS) is poised to revolutionize the landscape of robotics integration in manufacturing, presenting a compelling opportunity for industry players. Rapid Robotics, a leading RaaS provider, exemplifies the potential benefits, offering manufacturers the promise of setting up automated systems within weeks at a fixed cost, inclusive of comprehensive service and support.
Analyst’s Thoughts
According to Rajat Srivastava, Principal Analyst at BIS Research, “The U.S. robotics integration for the manufacturing market is poised for substantial growth, driven by a confluence of technological advancements, strategic industrial policies, and evolving workforce landscape. The market's growth trajectory is significantly bolstered by the aggressive adoption of AI and machine learning technologies, enabling robotic systems to perform complex tasks with greater autonomy and precision. Recent federal initiatives aimed at revitalizing the manufacturing sector and fostering innovation in robotics provide a conducive environment for market expansion. Moreover, the increasing emphasis on reshoring manufacturing operations, spurred by global supply chain disruptions, is catalyzing the demand for robotic integration as companies seek to enhance productivity and maintain a competitive edge. The market's growth is further supported by the rising trend of Industry 4.0, where interconnected and intelligent robotic systems play a pivotal role in achieving digital transformation. Hence, with these factors at play, the U.S. robotics integration for the manufacturing market is not just on a growth path but is also evolving the very fabric of manufacturing, steering it toward a future of efficiency, innovation, and economic resilience.”
U.S. Robotics Integration for the Manufacturing Market - Analysis and Forecast, 2024-2029
Focus on Market, Applications and Technologies
Frequently Asked Questions
Ans: Robotic integration refers to the process of incorporating robotic systems into existing workflows, manufacturing lines, or operational frameworks. It involves the design, setup, programming, and deployment of robotic units to perform specific tasks, often in collaboration with human workers or other automated systems. This integration is a pivotal aspect of modern manufacturing and industrial operations, signifying the transition toward smarter, more efficient production methodologies.
The benefits of robotic integration in the U.S. include increased productivity, enhanced precision and quality, cost reduction, improved workplace safety, flexibility and scalability, and competitive advantage.
Ans: In the U.S. robotics integration for the manufacturing market, key players are strategically reinforcing their market positions through significant investment in research and development, focusing on enhancing the intelligence, versatility, and autonomy of robotic systems. ?
Moreover, there's a strong emphasis on customizing solutions to meet specific industry needs, ensuring that robotic systems can be seamlessly integrated into diverse manufacturing environments. Companies are also focusing on service and support, offering comprehensive maintenance, training, and consultation services to ensure the smooth integration and operation of robotic systems.
Ans: For a new company entering the U.S. robotics integration for the manufacturing market, a strategic focus on several key areas is essential for staying ahead of the competition, such as embracing technological innovation, particularly in AI, machine learning, automation, and AR/VR, can significantly enhance service efficiency and accuracy.
Ans: The following can be seen as some of the USPs of the report:
• A dedicated section on growth opportunities and recommendations
• A qualitative and quantitative analysis of the U.S. robotics integration for the manufacturing market based on application and product
• Trend analysis of each application
• Country-level forecast
• A detailed company profile comprising established players and some start-ups that are capable of significant growth, along with an analyst view
Ans: Companies developing robotic system integrators and manufacturers of robots should buy this report.