机器人、协作机器人、人形软性机器人、群体机器人的未来：按技术和产业分類的全球市场 - 预测到 2030 年

人工智慧机器人正在透过使系统变得更加智慧、更具适应性和自主性来改变机器人技术的未来。

透过利用人工智慧处理即时资料、分析环境和做出独立决策的能力，这些机器人将大幅提高效率并减少各行业的错误。人工智慧电脑视觉使机器人能够识别物体、了解动态情况并执行精确的任务。在製造过程中，我们透过进行品质检查、精确组装零件以及最大限度地减少工作场所伤害来简化生产。医疗保健将受益于手术、病人照护和日常业务中的人工智慧机器人，从而提高安全性和业务效率。在农业领域，人工智慧机器人将优化作物收割、除草和生产力，减少对体力劳动的依赖。人工智慧自动驾驶汽车正在推动交通运输的发展，彻底改变出行方式。同时，在航太，这些机器人透过在未知地形中导航和协助太空人来协助太空探勘。人工智慧还将增强预测性维护，使机器人能够监控效能并检测问题，从而最大限度地减少停机时间。随着人工智慧技术的发展，它将推动各行业的创新，使机器人能够处理复杂的任务并适应特定需求，彻底改变自动化，实现更智慧、高效的未来。

“协作机器人的兴起正在缩小人与机器之间的差距，以创造更智能的未来。”

协作机器人（cobots）透过实现人与机器之间的无缝互动正在重塑机器人技术的未来。与单独操作的传统机器人不同，协作机器人旨在与人类一起安全地工作，从而提高各行各业的生产力。透过卸载重复性和危险的任务，工人可以专注于更复杂、更增值的活动。人工智慧、机器学习和感测器技术的最新进展使得协作机器人更加智慧、适应性更强，能够学习任务、适应新环境并在没有物理障碍的情况下运作。它的多功能性使其成为动态生产环境的理想选择，因为它可以轻鬆重新配置以适应不同的任务。借助碰撞和力检测等先进的安全功能，协作机器人可以创造更安全的职场，同时提高营运效率。作为工业 4.0 的关键组成部分，协作机器人与工业IoT(IIoT) 无缝集成，以优化工作流程并实现资料驱动的决策。透过解决劳动力短缺和日益增长的效率需求，协作机器人正在推动创新并改变人类在自动化中的角色，为以人性化的协作铺平了道路。

“软机器人透过为自动化带来灵活、适应性强的技术来推动创新。”

软机器人有望利用柔性、柔软的材料使机器人能够模仿生物体的自然运动，从而彻底改变自动化。这项技术创新提供了几个关键优势，包括增强的适应性、更安全的人机协作和具有成本效益的解决方案。在医学领域，软性机器人透过提供精细的协助并以最小的风险改善患者护理，正在彻底改变手术和復原。在农业领域，它能够实现更有效率、更永续的操作，例如在不损坏农作物的情况下收割作物。软性机器人也在製造业和物流中掀起波澜，它们能够小心地处理精密货物，从而减少产品损坏并提高生产效率。随着材料科学和人工智慧的进步推动更智慧、更强大的系统的发展，软性机器人的可能性不断扩大。研究人员致力于创造能够提高性能同时确保环境永续性的材料。随着这些技术的进步，软机器人有望透过补充人类能力和提高营运效率成为全球产业的重要组成部分。软性机器人注重安全性和灵活性，将推动重大技术创新，再形成产业并改善世界各地的生活品质。

本报告研究了全球机器人市场并展望了机器人技术的未来，探索了自动化、机器人智慧和协作机器人的进步以及机器人技术跨行业的融合。

目录

第一章执行摘要

第 2 章：机器人在製造业的演变

第 3 章 机器人技术类型

• 工业机器人
• 协作机器人（cobots）
• 服务机器人
• 移动机器人

第 4 章 机器人技术进步

• 机器人领域的人工智慧
• 人形机器人
• 软体机器人
• 群体机器人

第五章 全球机器人展望

• 北美洲
• 欧洲
• 亚太地区
• 其他地区

第六章 工业机器人的未来

• 车
• 医疗
• 电气和电子
• 太空探勘
• 废弃物管理
• 防御
• 娱乐

第七章：机器人科技塑造永续性的未来

第 8 章 机器人技术挑战

第 9 章结论：2030 年以后机器人技术的未来

AI-powered robots are transforming the future of robotics by making systems smarter, more adaptive, and autonomous. These robots leverage AI's ability to process real-time data, analyze environments, and make independent decisions, significantly enhancing efficiency and reducing errors across industries. AI-driven computer vision enables robots to identify objects, understand dynamic conditions, and perform precision tasks. In manufacturing, they streamline production by conducting quality inspections, assembling components with accuracy, and minimizing workplace injuries. Healthcare benefits from AI robots in surgeries, patient care, and routine tasks, improving safety and operational efficiency. In agriculture, AI-powered robots optimize crop harvesting, weed control, and productivity, reducing reliance on manual labor. Transportation is advancing with AI-driven autonomous vehicles, revolutionizing mobility, while in aerospace, these robots support space exploration by navigating uncharted terrains and assisting astronauts. AI also enhances predictive maintenance, allowing robots to monitor performance, detect issues, and minimize downtime. As AI technology evolves, it will drive innovation across industries, enabling robots to tackle complex tasks, adapt to specific needs, and revolutionize automation for a more intelligent and efficient future.

"The rise of cobots is bridging the gap between humans and machines for a smarter future"

Collaborative robots, or cobots, are reshaping the future of robotics by enabling seamless interaction between humans and machines. Unlike traditional robots that operate in isolation, cobots are designed to work safely alongside humans, boosting productivity across a wide range of industries. By taking over repetitive and hazardous tasks, they free workers to focus on more complex and value-driven activities. Recent advancements in AI, machine learning, and sensor technologies have made cobots smarter and more adaptable, allowing them to learn tasks, adjust to new environments, and operate without physical barriers. Their versatility makes them ideal for dynamic production settings, as they can be easily reconfigured to handle different tasks. With advanced safety features like collision detection and force sensing, cobots create safer workplaces while enhancing operational efficiency. As key components of Industry 4.0, cobots integrate seamlessly with the Industrial Internet of Things (IIoT), optimizing workflows and enabling data-driven decisions. By addressing labor shortages and rising efficiency demands, cobots are driving innovation, transforming human roles in automation, and paving the way for collaborative, human-centric workplaces.

"Soft robotics is driving innovation by bringing flexible and adaptive technology to automation"

Soft robotics is transforming automation by utilizing flexible, soft materials that allow robots to mimic the natural movements of living organisms. This innovation offers several key advantages, such as enhanced adaptability, safer human-robot collaboration, and cost-effective solutions. In healthcare, soft robots are revolutionizing surgery and rehabilitation by providing delicate assistance and improving patient care with minimal risk. In agriculture, they are enabling more efficient and sustainable practices, like harvesting crops without causing damage. Soft robotics is also making waves in manufacturing and logistics, where their ability to handle delicate items with care is reducing product damage and increasing productivity. The potential of soft robots continues to grow as advances in material science and artificial intelligence drive the development of smarter, more capable systems. Researchers are focused on creating materials that improve performance while ensuring environmental sustainability. As these technologies progress, soft robotics will become an integral part of industries worldwide, complementing human abilities and enhancing operational efficiency. By emphasizing safety and flexibility, soft robots are set to drive significant innovation, reshaping industries and improving the quality of life globally.

"North America's role in robotics innovation and technological growth"

North America is leading the way in shaping the future of robotics, with significant developments in the US, Canada, and Mexico. According to the International Federation of Robotics (IFR), the US accounts for 77% of total robot installations, driven by substantial investments in automation, especially in the automotive and electronics sectors. Companies like Tesla and General Motors are investing heavily in robotics to boost production efficiency and address labor shortages. In Canada, the automotive sector has seen a remarkable 95% increase in robot installations, reflecting a growing commitment to automation. Government incentives for robotics research and development further support this trend, fostering innovation in sectors like healthcare and logistics. In addition, Mexico is adapting to shifting economic dynamics, with nearshoring efforts bringing supply chains closer to home. As these countries continue investing in robotics and embracing technologies like AI and machine learning, North America's robotics market is expected to grow significantly in the coming future, strengthening its position as a global leader in innovation.

Research Coverage:

This report examines the future of robotics, exploring the advancements in automation, robotic intelligence, collaborative robots (cobots), and the integration of robotics into various industries. It offers a forward-looking analysis of how robotics will evolve and shape industries by enhancing efficiency, reducing costs, and driving innovation in manufacturing, healthcare, logistics, and more.

Report Scope

This report provides an in-depth analysis of the trends that will transform robotics in the coming years. Key areas of focus include the integration of AI and machine learning with robotics, the rise of autonomous systems, soft robotics, swarm robotics, advancements in collaborative robotics, and the development of robots for new applications. Additionally, it covers the role of robotics in supporting sustainability efforts, improving productivity, and enabling new business models. These insights are invaluable for manufacturers, technology providers, investors, and policymakers looking to secure a competitive advantage while aligning their strategies with the future evolution of robotics.

TABLE OF CONTENTS

1 EXECUTIVE SUMMARY

2. EVOLUTION OF ROBOTICS IN MANUFACTURING

3. ROBOTICS BY TYPE

• 3.1 INDUSTRIAL ROBOTS
• 3.2 COLLABORATIVE ROBOTS (COBOTS)
• 3.3 SERVICE ROBOTS
• 3.4 MOBILE ROBOTS

4. TECHNOLOGICAL ADVANCEMENTS IN ROBOTICS

• 4.1 AI IN ROBOTICS
• 4.2 HUMANOID ROBOTS
• 4.3 SOFT ROBOTICS
• 4.4 SWARM ROBOTICS

5. GLOBAL REGIONAL OUTLOOK ON ROBOTICS

• 5.1 NORTH AMERICA
• 5.2 EUROPE
• 5.3 ASIA PACIFIC
• 5.4 ROW

6. FUTURE OF ROBOTICS IN INDUSTRIES

• 6.1 AUTOMOTIVE
• 6.2 HEALTHCARE
• 6.3 ELECTRICAL & ELECTRONICS
• 6.4 SPACE EXPLORATION
• 6.5 WASTE MANAGEMENT
• 6.6 DEFENSE
• 6.7 ENTERTAINMENT

7. FUTURE OF ROBOTICS SHAPING SUSTAINABILITY

8. TECHNOLOGICAL CHALLENGES IN ROBOTICS

9. CONCLUSION: FUTURE OF ROBOTICS BEYOND 2030

List of Tables

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List of Figures

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