Machine Tending Robots Market Analysis and Forecast

Machine tending robots are specialized industrial systems designed to automate the loading, unloading, and overall management of machine operations within manufacturing environments. Equipped with advanced sensors and control systems, these robots execute repetitive tasks highly, enhancing productivity, improving workplace safety, and reducing labor costs. Their integration across various industrial sectors supports streamlined production processes and optimizes operational efficiency.

The machine tending robots industry was valued at $9,873.9 million in 2024 and is projected to reach $25,598.1 million by 2034, growing at a CAGR of 9.99% during the forecast period.

Industrial Impact

By automating monotonous, dangerous, or highly precise operations, machine tending robots have completely changed the production scene. Faster production cycles, less human error, and consistent product quality have resulted from their use. Furthermore, by reducing human exposure to potentially hazardous jobs, these devices have improved workplace safety.

Beyond automation, these robots promote innovation, assist company scalability, and reallocate workers to more strategic positions, all of which result in cost savings. They are positioned as important facilitators in the creation of smart industrial environments because to their alignment with the objectives of digital transformation.

The growing need for effective production solutions, continuous developments in artificial intelligence and sensor integration, and the general trend toward intelligent and adaptable automation technologies all contribute to the market's expansion.

Market Segmentation 

1. By Application

CNC Machine Tending

Injection Molding

Grinding and Polishing

Welding

Packaging and Sorting

2. By End-Use IndustryAutomotive

Electronics and Semiconductors

Metal and Machinery

Plastics and Packaging

Consumer Goods and Food Processing

3. By Robot Type

Articulated Robots

Cartesian Robots

SCARA Robots

Delta Robots

4. By Region

North America

Europe

Asia-Pacific

Rest-of-the-World

Recent Developments

In May 2024, ABB rolled out a novel machine tending cell that streamlines automation while alleviating labor shortages. The system employs advanced robotics to boost operational efficiency and minimize manual intervention in manufacturing processes.

In March 2025, Vention launched its innovative click-and-customize robotic work cells for both machine tending and welding applications. This solution is designed for rapid deployment, effectively addressing manufacturing labor challenges through enhanced automation.

In August 2024, Hurco revealed a strategic partnership with Kawasaki Robotics to offer comprehensive, industrial-grade robotic machine tending solutions. The collaboration is focused on optimizing manufacturing automation and mitigating the impact of workforce shortages.

Market Opportunity

Under-automated industries and small to mid-sized businesses (SMEs) have significant prospects. Automation is being used more and more in industries like consumer packaging, textiles, food processing, and pharmaceuticals to improve traceability, adhere to hygienic regulations, and fight growing labor costs.

The entry barriers for SMEs have been reduced by the availability of affordable, pre-configured robotic systems, which enable them to integrate automation with little capital input and customisation. This change is paving the way for robot integrators and manufacturers to enter new markets and achieve sustained growth.

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Conclusion

The market for machine tending robots is expanding at a revolutionary rate due to the growing demand for automation, improved accuracy, and increased operational efficiency. Machine tending robots are becoming an essential part of contemporary production processes as firms look to maximize productivity and lessen their reliance on human labor.

Key application areas include CNC machine tending are anticipated to dominate, and the market will expand more quickly due to the increasing usage of robots across a variety of sectors. Unrealized potential in SMEs and historically less mechanized industries offers a calculated path to future expansion.

In addition to changing industrial automation today, machine tending robots are laying the groundwork for tomorrow's smart factories.

Industrial Robots: Powering the Future of Smart Manufacturing

In today’s rapidly evolving industrial landscape, industrial robots are more than just machines — they’re the driving force behind productivity, precision, and innovation. From automotive to electronics, packaging to pharmaceuticals, industrial robots are transforming the way goods are produced, handled, and delivered.

Whether it’s assembling components, moving materials, or performing repetitive tasks with flawless consistency, industrial robots are at the core of modern automation. In this article, we’ll explore what industrial robots are, how they work, their types, benefits, and why more companies are investing in robotic automation than ever before.

What Are Industrial Robots?

Industrial robots are programmable, automated machines used to perform specific tasks in manufacturing or industrial environments. These tasks can include welding, painting, assembly, material handling, packaging, palletising, inspection, and testing.

Industrial robots are designed to replace or assist human workers in tasks that are dangerous, repetitive, or require extreme precision. They can be fixed or mobile, and often operate within a robotic cell or assembly line.

Types of Industrial Robots

Articulated Robots These have rotary joints and resemble a human arm. They are highly flexible and used for welding, assembly, and material handling.

SCARA Robots (Selective Compliance Articulated Robot Arm) Ideal for high-speed pick-and-place tasks, assembly, and packaging.

Cartesian Robots These operate on three linear axes (X, Y, and Z) and are great for CNC machines, 3D printing, and heavy load handling.

Delta Robots Known for speed and precision, they’re commonly used in packaging and pharmaceutical applications.

Collaborative Robots (Cobots) Designed to safely work alongside humans, cobots are ideal for small and medium enterprises seeking flexible automation.

Applications of Industrial Robots

Automotive: Welding, assembling chassis, and painting.

Electronics: Precise placement of micro-components.

Packaging: High-speed product picking, labeling, and boxing.

Pharmaceuticals: Sterile product handling and packaging.

Food & Beverage: Sorting, filling, and palletizing operations.

Benefits of Using Industrial Robots

Increased Productivity Robots can work 24/7 with consistent speed and accuracy, significantly increasing output.

Improved Product Quality Precision programming ensures that every task is performed identically, reducing defects and waste.

Reduced Labor Costs Robots minimize the need for manual labor in repetitive or hazardous jobs, saving costs over time.

Workplace Safety By taking over dangerous tasks, robots reduce the risk of injury to workers.

Faster Time-to-Market Automation accelerates the production cycle, helping companies meet market demands quicker.

Scalability and Flexibility Robotic systems can be reprogrammed or scaled to suit new products or production changes.

The Future of Industrial Robotics

The industrial robotics market in India and worldwide is growing at a remarkable pace, thanks to advances in AI, machine vision, IoT, and predictive maintenance. Robots are no longer confined to repetitive tasks — they are learning, adapting, and collaborating.

With the rise of smart factories and Industry 4.0, companies are leveraging robotics to optimise supply chains, reduce errors, and gain real-time data insights. As the demand for efficiency and customisation increases, so will the adoption of industrial robots across sectors.

Delta Stark Engineering: Your Partner in Industrial Automation

At Delta Stark Engineering, we specialize in designing and delivering high-performance industrial robots that meet your unique manufacturing needs. From pick and place systems to packaging automation, our robots are built for speed, precision, and long-term reliability.

We offer:

Customized automation solutions

Integration with existing systems

Full support and service across India

Whether you're upgrading your production line or building a smart factory from scratch, our robotic systems empower your business to operate smarter, safer, and faster.

Advancing Automation: Innovating Industries with Key Technologies

In today's dynamic industrial landscape, automation stands as a cornerstone of efficiency, safety, and sustainable progress. At Dropship Automation Solutions, we specialize in providing premium automation components essential for optimizing operations across diverse industries. In this article, we explore three pivotal components crucial for any automation setup: actuators, industrial robots, and SCADA systems. Whether you're upgrading existing systems or embarking on new installations, understanding these components is essential for achieving peak operational performance.

1. Actuators: Precision in Motion

What are Actuators in Automation? Actuators are mechanical or electromechanical devices that convert energy into motion, driving essential industrial processes with precision and reliability.

Key Types and Applications:

Types: Pneumatic actuators, hydraulic actuators, electric actuators

Applications: Valve control, robotics, material handling

Benefits: High precision, rapid response times, robust performance

Why Actuators Matter: Actuators play a crucial role in automation by enabling precise control over mechanical movements, ensuring optimal efficiency and productivity in industrial operations.

2. Industrial Robots: Transforming Manufacturing

What are Industrial Robots in Automation? Industrial robots are programmable machines designed to perform tasks traditionally handled by human workers, enhancing production capabilities and efficiency.

Key Features and Importance:

Types: Articulated robots, Cartesian robots, collaborative robots (cobots)

Functions: Assembly, welding, painting, palletizing

Applications: Automotive assembly lines, electronics manufacturing, logistics

Why Industrial Robots Matter: Industrial robots streamline manufacturing processes, improving accuracy, reducing cycle times, and enhancing workplace safety by automating repetitive or hazardous tasks.

3. SCADA Systems: Enhancing Control and Monitoring

What are SCADA Systems in Automation? SCADA (Supervisory Control and Data Acquisition) systems are software and hardware solutions used for real-time monitoring and control of industrial processes.

Key Components and Applications:

Components: Remote terminal units (RTUs), human-machine interface (HMI), communication infrastructure

Functions: Data acquisition, process visualization, alarm management

Applications: Power plants, water treatment facilities, oil and gas refineries

Why SCADA Systems Matter: SCADA systems facilitate centralized monitoring and control of complex industrial operations, optimizing efficiency, minimizing downtime, and ensuring regulatory compliance.

Integration for Seamless Automation

Imagine a scenario where:

Actuators ensure precise positioning and control in automated assembly lines.

Industrial robots collaborate seamlessly in manufacturing processes, enhancing production throughput.

SCADA systems monitor critical parameters in real-time, enabling proactive maintenance and operational adjustments.

Conclusion

Automation continues to redefine industrial processes by boosting productivity, ensuring operational reliability, and fostering sustainable growth. By integrating essential components like actuators, industrial robots, and SCADA systems, industries can achieve unparalleled efficiency, lower operational costs, and gain a competitive edge in today's global marketplace.

At Dropship Automation Solutions, we are committed to delivering cutting-edge automation solutions tailored to your specific needs. Explore our comprehensive range of automation components or contact us for personalized consultation and support on your automation journey.

Contact: +1 (234) 288-1755 Email: [email protected] Location: 1440 W. Taylor St #2555, Chicago, IL 60607

Robot Operating System Market Size, Share & Industry Trends Analysis Report by Robot Type (Articulated, SCARA, Cartesian, Collaborative, Autonomous Mobile, Parallel), Application (Pick & Place, Testing & Quality Inspection, Inventory Management), End User and Region - Global Forecast to 2028

What are the Key Concepts in Geometry? 

Geometry is the mathematical study of spatial properties and relationships of objects, including points, lines, angles, and surfaces. It involves understanding the dimensions and measurements of objects, analyzing how they relate, and exploring their behavior under transformations.  

The word “geometry” is derived from the Greek words geo (earth) and metron (measure), reflecting the subject’s origins in land measurement. Early civilizations used geometry to divide land, construct buildings, and map territories, giving rise to concepts that form the backbone of modern mathematics.  

A Brief History of Geometry  

The history of geometry dates to ancient times and spans several cultures. Key milestones include:  

Ancient Egypt and Babylon:  

The Egyptians used geometric principles to measure land after the Nile River floods.  

Babylonians applied geometry for agricultural planning and astronomy.  

2. Greek Geometry:  

The Greeks formalized geometry through logical reasoning. Euclid, often referred to as the “father of geometry,” compiled existing knowledge in his book The Elements.  

Pythagoras discovered the relationship between the sides of right-angled triangles (Pythagoras’ theorem).  

3. Indian Contributions:  

Ancient Indian mathematicians like Aryabhata and Brahmagupta contributed to the development of geometry, particularly in astronomy and trigonometry.  

4. Non-Euclidean Geometry (18th-19th Century):  

Mathematicians like Gauss, Riemann, and Lobachevsky developed new forms of geometry, including hyperbolic and spherical geometry.  

5. Modern Geometry:  

With the advent of computers, geometry has found applications in 3D modeling, graphics, artificial intelligence (AI), and space exploration.  

Types of Geometry  

Geometry can be divided into several branches, each with unique characteristics and applications:  

Euclidean Geometry  

This is the geometry taught in most schools, based on Euclid’s postulates. It deals with flat spaces and covers familiar concepts like points, lines, angles, and polygons.  

Examples: Angles in a triangle add up to 180°, and parallel lines never meet.  

2. Non-Euclidean Geometry  

In contrast to Euclidean geometry, this branch deals with curved surfaces. 

Types:  

Spherical Geometry: Used to study shapes on a sphere’s surface (e.g., Earth).  

Hyperbolic Geometry: Deals with negatively curved surfaces (useful in complex networks and theoretical physics). 

3. Coordinate Geometry  

Combines algebra and geometry to study shapes using a Cartesian plane (x-y coordinate system).  

Applications: Used to calculate distances, slopes, and areas of shapes plotted on a graph.  

4. Analytic Geometry  

Extends the concept of coordinate geometry to study curves and surfaces using equations.  

5. Differential Geometry  

Uses calculus to study the properties of curves and surfaces.  

Applications: Used in physics, particularly in Einstein’s theory of relativity.  

6. Fractal Geometry  

Studies complex patterns that are self-similar at different scales.  

Examples: Fractals are found in nature, such as in snowflakes, coastlines, and tree branches.  

Key Concepts in Geometry  

Below are the core principles and topics that students encounter when studying geometry:  

Points, Lines, and Angles 

Point: A location in space with no size or dimension.  

Line: A straight path extending infinitely in both directions.  

Angle: Formed when two lines meet at a point (vertex).  

Applications of Geometry in the Real World  

Architecture and Engineering  

Architects use geometry to design buildings and ensure structural stability.  

Engineers apply geometry in constructing bridges, tunnels, and machinery.  

2. Computer Graphics and Animation  

3D models and virtual environments in video games and movies rely on geometric principles.  

3. Astronomy and Space Science  

Astronomers use geometry to calculate distances between celestial objects and model planetary orbits.  

4. Robotics and AI  

Robots need geometric algorithms to navigate spaces and perform tasks efficiently.  

5. Art and Design  

Artists use geometric patterns and symmetry to create visually appealing designs.  

Importance of Geometry for Students  

Studying geometry offers more than just academic knowledge—it cultivates essential life skills, including:  

Logical Reasoning: Students learn to think logically and build structured arguments.  

Spatial Awareness: Geometry helps in visualizing objects and understanding their relationships.  

Problem-Solving Skills: Geometric concepts encourage creative approaches to challenges.  

Additionally, geometry forms the basis for advanced topics like trigonometry, calculus, and physics, making it essential for students pursuing careers in STEM fields.  

Geometry is much more than a branch of mathematics; it’s a powerful tool that shapes how we see and interact with the world. From the design of towering skyscrapers to the precision of spacecraft trajectories, geometry is all around us. Mastering it not only enhances mathematical skills but also nurtures critical thinking, creativity, and problem-solving abilities.  

For students looking to deepen their understanding of geometry, platforms like Tutoroot offer interactive and engaging lessons tailored to various academic levels. Geometry opens doors to exciting possibilities, inspiring learners to explore the beauty and logic underpinning the world. Tutoroot offers a comprehensive online maths tuition program designed to help students succeed. With experienced tutors, personalised learning plans, and a wealth of educational resources, Tutoroot provides the support and guidance students need to excel in maths. 

What is a Cartesian robot, and how is it utilized in automation?

A cartesian robot is also known as a Gantry robot. It is a type of robotic system which moves in straight lines along the orthogonal axes. It is commonly referred to as the X, Y and Z axes. These robots are bolts on a coordinate system. They follow Cartesian geometry, and therefore, they have their name.

It involves movements in right-angled directions. Each axis of movement is powered by either a motorized system or a linear actuator. It enables the robot to move accurately in a predictable and controlled manner.

Critical characteristics of Cartesian robots

The following are the essential characteristics of cartesian robots.

Structure

Caterina robots consist of three linear actuators positioned perpendicular to each other. This enables the robot to move in three-dimensional space. Some designs might include an additional rotational axis, referred to as the "R-axis." It helps enhance the robots' capability.

Design simplicity

The construction is straightforward; therefore, cartesian robots are relatively simple to function, design, and maintain compared to the other types of Industrial robotics. Such simplicity also translates to excellent eater reliability and lower costs.

Scalability

The linear axes of a cartesian robust can be scaled and customized to meet particular operational needs. The length of each axis can be shortened or extended on the basis of the size of the work area, making it significantly adaptable to different applications.

High precision

Cartesian robots are known for their precision and accuracy. It makes them ideal for tasks that require meticulous positioning and movement. The linear motion control of the linear robot helps it follow predefined paths with minimal errors, contributing to high repeatability. Cartesian robots are widely employed in industrial automation due to their affordability, cost-effectiveness, and ease of integration.

Their linear action is perfect for many different kinds of jobs, especially those that need basic, repeated movements. The following are some of the leading automation applications for Cartesian robots:

Material Management

Every Cartesian robot is extensively utilized in material handling applications. They can handle delicate parts with greater accuracy and reproducibility, lowering the possibility of damaging the materials. They are employed in sectors where precision and consistency are essential.

3D printing

3D printing is one of the most renowned uses for Cartesian robots. This makes it possible to precisely deposit material in layers to form intricate patterns and motifs. Cartesian robots are perfect for usage in tiny desktop 3D printers and extensive industrial additive manufacturing equipment because of their precision and scalability. The printed products' structural integrity and dimensional precision are guaranteed by their exact movement along the three axes.

Final words

Cartesian robots are a vital component of the automation landscape. Their adaptability across various sectors is demonstrated by their application in palletizing, automated inspection, 3D printing, material handling, and CNC machining.

As automation technology advances, Cartesian robots are expected to significantly enhance operational precision and efficiency in manufacturing and other industries. Reach out to Igus for the best products and services. We ensure you the most affordable yet proficient and effective products. So, contact us and communicate your requirements without any delay!

Types of Industrial Robots and Their Role in Automated Manufacturing

In the contemporary manufacturing environment, the integration of industrial robots has significantly transformed production processes, driving enhanced efficiency, accuracy, and flexibility. The evolution of robotics technology has introduced various types of industrial robots, each tailored to meet distinct automation requirements. This article explores the different types of industrial robots, their specific applications, and the critical role of automation advisory and technology scouting in optimizing manufacturing operations.

Overview of Industrial Robots

Industrial robots are categorized based on their design, functionality, and intended applications. The primary types include articulated robots, SCARA robots, delta robots, cartesian robots, and collaborative robots (cobots). A thorough understanding of these robot types is essential for selecting the most appropriate robot for a given manufacturing task.

1. Articulated Robots

Articulated robots are the most prevalent type of industrial robot, characterized by their rotary joints that provide a wide range of motion. Typically, these robots feature four to six axes, enabling them to perform tasks with high precision and flexibility. Due to their versatility, articulated robots are commonly employed in operations such as welding, assembly, material handling, and machine tending. Their ability to maneuver in complex angles makes them indispensable in industries like automotive and aerospace.

2. SCARA Robots

Selective Compliance Articulated Robot Arm (SCARA) robots are designed for tasks that demand rapid and precise movements within confined spaces. These robots have a fixed base and three vertical joints, which make them particularly suitable for pick-and-place operations, assembly, and packaging. SCARA robots are favored for their rigid structure, which ensures stability and accuracy in repetitive tasks, often in electronics and consumer goods manufacturing.

3. Delta Robots

Delta robots, also known as parallel robots, have a distinctive spider-like design featuring three arms connected to a common base. These robots are renowned for their exceptional speed and precision, making them ideal for high-speed applications such as picking, packing, and sorting. Industries like food processing, pharmaceuticals, and electronics frequently utilize delta robots due to their ability to perform quick and accurate movements, essential for maintaining production efficiency.

4. Cartesian Robots

Cartesian robots, or gantry robots, operate on three linear axes (X, Y, and Z) and are recognized for their simplicity and precision. These robots are often employed in applications such as CNC machining, 3D printing, and automated storage and retrieval systems. Cartesian robots are valued for their straightforward design and ease of programming, making them a preferred choice for tasks that require linear motion and high accuracy.

5. Collaborative Robots (Cobots)

Collaborative robots, commonly referred to as cobots, are engineered to work alongside human operators, enhancing both productivity and safety in manufacturing settings. Cobots are equipped with advanced sensors and safety mechanisms that enable safe interaction with human workers. These robots are widely used in assembly, quality inspection, and material handling, where human-robot collaboration can streamline workflows and improve overall efficiency.

Applications of Industrial Robots

The diverse range of industrial robots is applied across various sectors of manufacturing, with each type of robot excelling in specific tasks that contribute to overall production effectiveness.

Welding: Articulated robots are highly valued in welding applications due to their precision and ability to handle complex welding tasks in industries such as automotive and aerospace.

Assembly: SCARA robots and cobots are ideal for assembly processes, where their speed and accuracy are crucial for efficiently assembling components.

Material Handling: Cartesian and articulated robots are often used for material handling tasks, including moving heavy items, loading and unloading machinery, and palletizing products in distribution centers.

Packaging: Delta and SCARA robots are commonly employed in packaging operations, where their quick and precise movements are essential for sorting, packing, and labeling products.

Quality Inspection: Cobots are increasingly used in quality inspection, where their ability to work alongside human inspectors enhances the detection of defects and ensures high product quality.

The Role of Automation Advisory and Technology Scouting

Choosing the appropriate type of industrial robot for a specific application requires careful consideration of factors such as the nature of the task, production demands, and budget constraints. This is where automation advisory services and technology scouting play a pivotal role.

Automation Advisory

Automation advisory involves consulting with experts who assess manufacturing operations and recommend the most suitable automation solutions. These experts analyze production processes, identify bottlenecks, and suggest ways to integrate robots to improve efficiency. By leveraging insights into the latest robotic technologies, manufacturers can optimize their production processes, achieving enhanced performance and cost efficiency.

Technology Scouting

Technology scouting focuses on researching and identifying emerging robotic technologies that can benefit manufacturing operations. Staying informed about the latest advancements enables manufacturers to adopt cutting-edge solutions that drive innovation and improve competitive advantage. Technology scouting also helps in identifying scalable robotic solutions that can evolve with a company’s production needs, ensuring long-term growth and sustainability.

Conclusion

The integration of various types of industrial robots has significantly impacted manufacturing by enhancing efficiency, precision, and flexibility. Articulated robots, SCARA robots, delta robots, cartesian robots, and cobots each serve unique functions across different industrial applications. Utilizing automation advisory and technology scouting ensures that manufacturers select the right robots for their specific needs, optimizing production processes and maintaining a competitive edge. As technology continues to advance, the role of industrial robots in manufacturing will only become more crucial, driving innovation and fostering growth across the industry.

Robotic & Automated Solutions provides expert guidance in harnessing effective advisory services and automation technologies, drawing from extensive experience in industrial automation to support manufacturers in achieving their strategic objectives.

Industrial Paint Robots Market Regions and Growth Status 2032

The Reports and Insights, a leading market research company, has recently releases report titled “Industrial Paint Robots Market: Global Industry Trends, Share, Size, Growth, Opportunity and Forecast 2024-2032.” The study provides a detailed analysis of the industry, including the global Industrial Paint Robots Market share, size, trends, and growth forecasts. The report also includes competitor and regional analysis and highlights the latest advancements in the market.

Report Highlights:

How big is the Industrial Paint Robots?

The global industrial paint robots market size reached US$ 2.4 billion in 2023. Looking forward, Reports and Insights expects the market to reach US$ 5.3 billion in 2032, exhibiting a growth rate (CAGR) of 9.1% during 2024-2032.

What are Industrial Paint Robots Market?

Industrial paint robots are automated systems engineered to apply paint and coatings with high precision and efficiency in industrial environments. These robots, featuring advanced control systems and spraying mechanisms, are programmed to manage tasks ranging from surface preparation to final coat application. They provide consistent, high-quality finishes, reduce waste, and lower labor costs. Commonly used in industries like automotive, aerospace, and manufacturing, industrial paint robots boost productivity, enhance safety by minimizing human exposure to hazardous materials, and ensure uniform results across extensive production runs.

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What are the growth prospects and trends in the Industrial Paint Robots Market industry?

The industrial paint robots market growth is driven by various factors and trends. The industrial paint robots market is expanding swiftly as manufacturers increasingly turn to automation to achieve high-quality and consistent coatings. Technological advancements in robotics are fueling this growth, providing enhanced precision, efficiency, and safety in paint applications. Sectors like automotive, aerospace, and general manufacturing are adopting these robots to boost productivity, cut labor costs, and reduce material waste. As companies strive to optimize their processes and adhere to rigorous quality standards, the demand for industrial paint robots continues to rise, with leading players investing in innovative solutions to meet the changing needs of the industry. Hence, all these factors contribute to industrial paint robots market growth.

What is included in market segmentation?

The report has segmented the market into the following categories:

By Robot Type:

Articulated Robots

Cartesian Robots

Selective Compliance Assembly Robot Arm (SCARA) Robots

Collaborative Robots

By End-Use Industry:

Automotive

Aerospace

Electronics

Furniture and Woodworking

Metal and Machinery

Others

Market Segmentation By Region:

North America:

United States

Canada

Europe:

Germany

United Kingdom

France

Italy

Spain

Russia

Poland

BENELUX

NORDIC

Rest of Europe

Asia Pacific:

China

Japan

India

South Korea

ASEAN

Australia & New Zealand

Rest of Asia Pacific

Latin America:

Brazil

Mexico

Argentina

Rest of Latin America

Middle East & Africa:

Saudi Arabia

South Africa

United Arab Emirates

Israel

Rest of MEA

Who are the key players operating in the industry?

The report covers the major market players including:

ABB Ltd.

Fanuc Corporation

Yaskawa Electric Corporation

KUKA AG

Kawasaki Heavy Industries Ltd.

Durr AG

Comau S.p.A.

Stäubli International AG

Universal Robots A/S

Nachi-Fujikoshi Corporation

Epson Robotics

Omron Corporation

CMA Robotics S.p.A.

FANUC Corporation

KAWASAKI Robotics GmbH

Discover more: https://www.reportsandinsights.com/report/industrial-paint-robots-market

If you require any specific information that is not covered currently within the scope of the report, we will provide the same as a part of the customization.

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Our offerings include comprehensive market intelligence in the form of research reports, production cost reports, feasibility studies, and consulting services. Our team, which includes experienced researchers and analysts from various industries, is dedicated to providing high-quality data and insights to our clientele, ranging from small and medium businesses to Fortune 1000 corporations.

Contact Us:

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Machine Tending Robots Market | BIS Research

The machine tending robots market is experiencing robust growth, fueled by rapid technological advancements and a rising demand for automation across various industrial sectors. These robots' versatility in streamlining industrial processes is demonstrated by their extensive use in CNC machine tending, injection molding, grinding and polishing, welding, packaging, sorting, and other tasks. Machine tending robots dramatically increase productivity, accuracy, and efficiency by meeting the particular requirements of each process. Automotive, electronics and semiconductors, metal and machinery, plastics and packaging, consumer products, and food processing are some of the major industries that profit from these systems. Global innovation and strategic investment in industrial robotics are fueled by the availability of a variety of robot types, including articulated, Cartesian, SCARA, and delta robots, which offer customized automation solutions.

The machine tending robots industry was valued at $9,873.9 million in 2024 and is projected to reach $25,598.1 million by 2034, growing at a CAGR of 9.99% during the forecast period.

Industrial Impact

Machine tending robots have revolutionized industrial manufacturing by boosting productivity and operational efficiency. By automating high-precision, repetitive activities, these robotic systems shorten manufacturing cycle times and lower human error. By reducing the dangers associated with manual labor, their integration improves workplace safety, streamlines operations, and guarantees constant quality.

In addition to improving operations, these robots reduce labor-intensive tasks, which frees up resources for strategic expansion and innovation. This lowers costs and boosts competitiveness. Machine tending robots are essential to digital transformation, scalability, and maintaining long-term growth as companies develop.

Demands for efficiency, cost reductions, and advancements in AI and sensor technologies—which make it possible for more intelligent and flexible robotic solutions across a range of industries—are what propel growth.

Market Segmentation 

1. By Application

CNC Machine Tending

Injection Molding

Grinding and Polishing

Welding

Packaging and Sorting

2. By End-Use Industry

Automotive

Electronics and Semiconductors

Metal and Machinery

Plastics and Packaging

Consumer Goods and Food Processing

3. By Robot Type

Articulated Robots

Cartesian Robots

SCARA Robots

Delta Robots

4. By Region

North America

Europe

Asia-Pacific

Rest-of-the-World

Recent Developments

In May 2024, ABB rolled out a novel machine tending cell that streamlines automation while alleviating labor shortages. The system employs advanced robotics to boost operational efficiency and minimize manual intervention in manufacturing processes.

In March 2025, Vention launched its innovative click-and-customize robotic work cells for both machine tending and welding applications. This solution is designed for rapid deployment, effectively addressing manufacturing labor challenges through enhanced automation.

In August 2024, Hurco revealed a strategic partnership with Kawasaki Robotics to offer comprehensive, industrial-grade robotic machine tending solutions. The collaboration is focused on optimizing manufacturing automation and mitigating the impact of workforce shortages.

Market Opportunity

The machine tending robots market holds substantial untapped potential, particularly within under-automated sectors and small to medium-sized enterprises (SMEs). The need for automation is increasing in sectors including consumer goods packaging, textiles, food processing, and pharmaceuticals due to factors like higher traceability requirements, stringent hygiene regulations, and expanding labor costs.

Furthermore, SMEs can now implement automation without requiring significant customisation or a large upfront investment thanks to the availability of affordable, pre-engineered robotic systems. As smaller organizations look to improve operational efficiency, lower manual errors, and stay competitive in quickly changing industries, this change is creating new growth opportunities. For robot manufacturers and integrators, entering these markets offers a significant chance to gain market share and support sustained industry growth.

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Learn more about Robotics and Automation Vertical. Click Here!

Conclusion

The machine tending robots market is undergoing a significant transformation, fueled by the growing demand for automation, improved precision, and operational efficiency across various industries. Machine tending robots are becoming a crucial part of contemporary industrial operations as manufacturers look for ways to increase productivity and lessen their reliance on people. This progress is anticipated to be led by important application areas like CNC machine tending, with adoption being further fueled by a variety of robot types and industry-specific modifications. The market's unrealized potential is highlighted by new prospects in small and medium-sized businesses (SMEs) and under-automated sectors. All things considered, machine tending robots will be essential to the development of smart manufacturing and industrial automation in the future.

Industrial Robotics Market - Forecast(2024 - 2030)

Industrial Robotics Market Overview

Industrial Robotics Market size was valued at $49.25 Billion in 2030, and it is estimated to grow at a CAGR of 11.9% during 2024-2030. The advent of numerous sorts of techniques committed to production control and the introduction of automation solutions are the key components of present production improvement policies. In addition, the increasing awareness of industrial robots has resulted in their deployment ranging from manufacturing to the healthcare industry. Moreover, this market is majorly driven by a surge in labor charges worldwide, which in turn has forced manufacturers to replace human labor with machines. Asia and Europe are the key growth regions of the world, with leading players, namely ABB, Fanuc, KUKA, Kawasaki, and the Yaskawa Electric Corporation being based out in the region. Collaborative Robots (Cobots) are revolutionizing the industry by working alongside humans without the need for safety cages. This trend is gaining momentum due to the increasing demand for automation in smaller factories and their expanding role in diverse industries. Cobots enhance flexibility, efficiency, and safety in manufacturing processes. Simultaneously, advancements in AI and IoT are driving a paradigm shift in industrial robotics. AI empowers robots to learn and adapt, making them more intelligent and versatile. The integration of IoT enables robots to communicate with each other and other systems, fostering enhanced collaboration and efficiency. This synergy is propelling the industrial sector towards Industry 4.0, where smart manufacturing processes redefine automation standards. As a result, the industrial robotics market is evolving with the widespread adoption of Cobots and the integration of AI and IoT, ushering in a new era of intelligent and collaborative automation. Hence these benefits are analyzed to drive the market in the forecast period 2024-2030.

Report Coverage

The report: “Industrial Robotics Market Forecast (2024-2030)”, by IndustryARC, covers an in-depth analysis of the following segments of the Industrial Robotics Market.

By Category: Articulated Robot, Cylindrical Robot, Linear Robots, Cartesian & Gantry, Parallel Robot, SCARA Robot, Spherical Robots, Dual arm, Others

By Configuration: Mounted, Cobots/ Collaborative Robots)

By Components: (Manipulator, Sensor Devices, Robot Tooling, RCU - Robot Controller Unit

By payload: Up to 5KG, 5.1 to 10 KG, 10.1 to 15 KG, and More than 15 Kg

By End User: Automotive and Autoparts, Electrical & Electronics, Food and Beverages, Metal Fabrication and Palletization, Medical, Chemical, and Life Sciences, Others

By Geography: North America, South America, Europe, APAC, RoW.

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Key Takeaways

APAC dominated the Industrial Robotics Market in 2023 with a share of 58%. High and early adoption of advanced technologies is set to boost the market growth. The strong financial position allows it to invest heavily in the adoption of latest tools and technologies for ensuring effective business operations.

Parallel robots are estimated to grow at a CAGR of 11.8% market. These Robots will be formed by connecting parallelograms to a common base and are also referred to as spider-like robots.

Robotic automation enables to achieve innovation in a quick and impactful way which can drive quantifiable benefits to the industrial automation industry.

Category - Segment Analysis

Parallel robots are estimated to grow at a CAGR of 11.8% market. These Robots will be formed by connecting parallelograms to a common base and are also referred to as spider-like robots. These robots are mostly used in the food industry, pharmaceuticals, and electronic industries. As they can do delicate/precise movements. Similarly, these robots will use three servo motors and are very high in speed and perfectly suited for light-duty tasks within small working zones. These are the main reasons which tends to be used for high-speed sorting and packaging in the food, pharmaceutical, and electronic industries. In addition, the delta robot market is anticipated to be driven by the trend of miniaturization in the manufacturing industry, moreover, smaller sizes of objects lead to increased challenges of various micro-assembly tasks, expected to increase the demand for delta robots. Moreover, technologically advanced machine vision 3D cameras are being integrated with delta robots to enhance their efficiency and accuracy. In addition, Delta robots with vision systems can perform lethargic, dull, and monotonous tasks at high speed and accuracy with minimum imperfections and scrap. This will improve the performance of delta robots and increase their adoption in end-user industries. Additionally, several companies are investing heavily in research and development activities for these robots. In 2022, Omron expanded its i4H SCARA lineup with food-grade robots, catering to the food and beverage and packaging industry. These new additions prioritize safe handling, ensuring compliance with the industry's stringent hygiene standards. Similarly, companies such as ABB, KUKA AG, and so on are investing heavily in the development of advanced robots in the forecast period 2024-2030.

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End User - Segment Analysis

Electrical & Electronics is the fastest-growing segment in the Industrial Robotics Market and is estimated to grow at a CAGR of 9.4%. The Electronics sector has also been slowly emerging as a major end-user for the Industrial Robotics Market with its higher adaptability due to growing digitalization. Since accuracy and precision are of important factors in an electronic production plant, thus due to ease of use, the electronics sector has been proactively adopting industrial robots, boosting its market growth. With the growing shift towards automation of manufacturing processes, industries like electrical and electronics have been widely deploying industrial robots to perform high-precision tasks, thus improving productivity standards. The usage of industrial robots helps electrical and electronics companies to automate almost every manual task while adding value to their business growth. Thus, growing adoption has been causing a positive impact on the market growth of industrial robots. With growing development of the electronics sector due to rising demands for electronic devices by consumers has been also acting as a major driver toward higher requirements for industrial robots. As industries are shifting towards smart technologies, industrial robots are gaining much popularity in the electronics sector due to their capabilities of performing tasks like integration and assembling of various small-sized components within electronic devices such as mobile phones, computers, and many others more efficiently within less time intervals. Since electronics manufacturers have to work under tight profit margins, industrial robots act as a cost-effective solution for improving the automation standards in their industry. Industrial Robots are used in applications ranging from cutting metal housings to assembling miniature components on boards, to applying adhesives and polishing surfaces, thus performing quality inspections and packing of finished products, at lower costs. Moreover, in the electrical and electronics sector, industrial robots are utilized mainly in assembly, screw tightening, electronic parts insertion as well as inspection processes as the robots are highly capable of sustaining harsh working environments. Such growing deployments help the industry to continue with their production process with quality preservation even at times of lack of skilled labor. Additionally, with innovations in the field of industrial robotics, lightweight and smaller robots are facing high demands in this sector.

Geography- Segment Analysis

APAC dominated the Industrial Robotics Market in 2023 with a share of 58%, followed by Europe and North America. High and early adoption of advanced technologies in countries such as India, and China is set to boost the market growth. The strong financial position allows it to invest heavily in the adoption of latest tools and technologies for ensuring effective business operations. The Chinese government’s ‘Made in China 2025’ policy aims at improving the competitiveness of Chinese companies through automation. According to the Ministry of Industry and Information Technology, in 2022, China's industrial robot output grew by 5.4% to 222,000 units in the first half of the year. Service robot production surged by 9.62% to 3.53 million units. China maintained its global lead in industrial robot installations in 2022, capturing over 50% of the market share. Moreover, the automotive industry is the major adopter of industrial robotics with a wide variety of applications and thus the growing automotive industry in this region will propel the market. Companies such as BAIC Motors, and Changan Automobile Group, have been investing heavily in the adoption of robotics in the forecast period 2024-2030. In addition, the launch of ‘Make in India’ has increased the focus on the Indian manufacturing sector, which is set to be among the fastest-growing markets in the APAC region as well as globally. The manufacturing sector’s growth output has increased and is projected to exhibit high growth. For instance, the government of India has committed to investing more than $13 billion in industrial robotic R&D. The government estimates the manufacturing sector value could reach $1 trillion by 2025. Major companies such as GE, Bosch, and Panasonic are planning to invest in the country which would boost India’s economic growth.

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Drivers – Industrial Robotics Market Robotic Process Automation and Artificial Intelligence Automation Spending Driving the Growth of Industrial Robots

The Robotics process automation landscape has changed in the past couple of years and has evolved from an emerging factor for the industrial robotics industry. Robotic automation enables to achieve innovation in a quick and impactful way which can drive quantifiable benefits to the industrial automation industry. Across the globe, automation companies are investing lots of capital to develop and innovate new technology in research and development. In 2023, ABB committedto investing $280 million in Sweden's Västerås to boost its European Robotics hub, catering to rising demand for AI-driven collaborative and industrial robots. The expanded campus, aligned with ABB's local production strategy, aims to enhance capacity by 50%, meeting evolving market needs amid supply chain challenges. Similarly, companies such as Mitsubishi Electric Corp, Ellison, and so on are investing heavily for the development of industrial robots in the forecast period. Some of the key factor affecting robotic process automation includes process with higher automation potential, with higher headcount reduction that offer a great cost saving to the manufacturers. Robotic Process Automation (RPA) recurring costs including licensing, hosting, and monitoring vary significantly by vendor and type of solution, the lower the recurring cost for RPA, the higher the cost saving. Various service providers are implementing RPA tools in various areas of end-user processes focusing on achieving consistency, risk reduction, and cost reduction factors.

Rising Labor Costs Amidst the Aging Workforce to Boost the Industrial Robots Demand

The labor cost is highly significant in the total industrial operating cost, making generally 62%-65% of the total cost. In majority of the cases, manual jobs typically consist of two categories of staff: direct and indirect where industries cover an area of more than 2, 00,000 square feet. Direct staff is responsible for executing the process while indirect staff is for the back-end support for direct staff. The presence of both direct and indirect staff coupled with department managers presents a crucial cost in operating a warehouse. For instance, according to the U.S. Bureau of Labor Statistics' Employment Cost Index, wages and salaries rose by 4.3% in the 12 months ending December 2023, while benefit costs increased by 3.8% over the same period. Moreover, according to the U.S. Bureau of Labor Statistics,total nonfarm payroll employment increased by 353,000 in January, maintaining the momentum from December's gain of 333,000. Throughout 2023, employment rose by an average of 255,000 jobs per month. As average hourly earnings will rise further amidst the rising global inflation with weekly hours to remain constant or decline in the coming years, the operating costs are bound to advance. Apart from this, the developing nations have seen constant growth in the aging workforce resulting in issues related to safety, quality control, and productivity. Thus, the automation of industries has become a notable means to tackle the rising wages and workforce age. This has resulted in industrial operators relying upon robotics to provide a convenient and efficient way of reducing operational costs while simultaneously maintaining productivity at optimum levels.

Challenges – Industrial Robotics Market Limited Flexibility of Robots for Handling Skus Posing Challenge for Industrial Robotics

The dawn of electronic commerce enabled by the increasing accessibility to mobile devices has resulted in consumers shopping online from a multitude of merchandisers. As the delivery to the consumer in working time of 3-5 days is crucial for retailers, it has resulted in multi-varied stock-keeping units (SKUs) and caseloads. This scenario often becomes challenging in the Food & Beverage sector where companies need to address the consumer demand at a much faster pace. The robots utilized in the process industries are simply robots used in manufacturing operations that only require limited flexibility in handling pallets. Although over time, robots have developed to handle the SKUs with greater precision and accuracy but still require a great deal of evolution in handling mixed SKUs with consistent speed and accuracy without damaging the product. Hence these kinds of challenges hamper the market growth in the forecast period 2024-2030.

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Industrial Robotics Market Landscape

Product launches, acquisitions, Partnerships, and R&D activities are key strategies adopted by players in the industrial robotics market. Industrial Robotics' top 10 companies include Fanuc, KUKA AG, ABB Group, Yaskawa Electric Corporation, EPSON, Kawasaki Heavy Industries, Ltd, Mitsubishi Electric Corporation, Omron Adept Technology, Staubli, Denso Corporation, and Automation among others.

Ø  In November 2023, ABB Robotics introduced the IRB 930 SCARA robot, enhancing pick-and-place and assembly tasks in electronics, automotive, and renewable energy sectors. With a 10% increase in throughput and 200% stronger push-down capability, it optimizes productivity and quality, addressing evolving industry needs for heavier workpieces and force-intensive operations.

Ø  In November 2023, Yaskawa Electric Corporation has unveiled the MOTOMAN NEXT series, pioneering adaptive robotics in the industrial sector. With five models boasting payloads ranging from 4kg to 35kg, these robots possess autonomous adaptivity, a groundbreaking feature for making environment-based judgments, driving innovation in industrial automation

Ø  In April 2023, Doosan Robotics introduced the NSF-certified E-SERIES, a line of collaborative robots tailored for the food and beverage sector. This launch expands their product range with 13 new offerings, marking a significant milestone in the cobot market.

Warehouse Robotics Market - Forecast(2024 - 2030)

Warehouse Robotics Market Overvie

The Global Warehouse Robotics Market size is projected to reach US$6.2 billion by 2030, growing at a CAGR of 12% from 2024 to 2030. The Warehouse Robotics Market encompasses the automation sector dedicated to developing, deploying, and utilizing robotic systems within warehouse and distribution center settings. These robots undertake tasks like picking, sorting, packing, and transportation, aiming to boost operational efficiency, enhance order accuracy, ensure safety, and minimize labor costs. A pivotal trend influencing this market is the integration of cutting-edge technologies like Artificial Intelligence (AI), machine learning, and the Industrial Internet of Things (IIoT). These advancements empower robots to operate autonomously, make real-time decisions, and communicate seamlessly with other warehouse systems, driving higher productivity, accuracy, and adaptability. E-commerce's surge significantly propels the warehouse robotics market forward. With online shopping's exponential growth, retailers and logistics firms face mounting pressure to swiftly and accurately fulfill orders. Warehouse robots offer a scalable solution to manage these demands, enabling companies to optimize order fulfillment processes and navigate peak periods efficiently. Moreover, there's a mounting emphasis on warehouse digitalization and inventory management, spurred by the quest for enhanced visibility and control over inventory levels. Robotics technologies such as automated storage and retrieval systems (AS/RS) and sortation robots play a pivotal role in optimizing warehouse space usage and inventory tracking. The factors such as the proliferation of advanced technologies, the expansion of e-commerce, and the increasing focus on operational efficiency and safety are expected to drive market expansion in the foreseeable future.

Report Coverage

The report: “Warehouse Robotics Industry Outlook – Forecast (2024-2030)” by IndustryARC, covers an in-depth analysis of the following segments in the Warehouse Robotics industry.

By Product Type: Autonomous Mobile Robot (AMR), Articulated Robots, Cylindrical Robots, SCARA Robots, Collaborative Robots, Parallel Robots, Cartesian Robots and Others.

By Payload Capacity: less than 20Kg, 20-100Kg, 100-300Kg and greater than 300Kg.

By System Type: Knapp Open Shuttle, Locus Robotics System, Fetch Robotics Freight, Scallog System and Swisslog Carrypick.

By Components: Programmable Logic Controller, Microprocessors and Microcontrollers, Actuators, Sensors and RF Module.

By Software: Warehouse management system, Warehouse execution system, Warehouse control system and Others.

By Function: Pick & Place, Assembling & Dissembling, Transportation, Sorting & Packaging and Others.

By End-use Industry: E-commerce, Automotive, Consumer Electronics, Food & Beverages, Healthcare, Metal & Machinery, Textile, Chemical and Others.

By Geography: North America (the US, Canada and Mexico), South America (Brazil, Argentina and Others), Europe (the UK, Germany, France, Italy, Spain and Others), APAC (China, Japan, South Korea, India, Australia and Others) and RoW (the Middle East and Africa).

Key Takeaways

• In the Warehouse Robotics market report, the autonomous mobile robots’ segment is analyzed to grow at a significant CAGR of 14.9% due to its high accuracy, increased efficiency and widespread applications across industry verticals.

• The E-commerce industry is expected to grow at the highest rate with a CAGR of 15.2% owing to factors such as rising demand for distribution center automation, fulfillment automation, growing demand for order accuracy and rising competition among the companies.

• North America held the largest market share of 34% in 2023 in the global Warehouse Robotics Market, owing to factors such as rapid R&D investments towards robotics and increasing adoption of robots for process automation.

Warehouse Robotics Market - Forecast(2024 - 2030)

The Global Warehouse Robotics Market size is projected to reach US$6.2 billion by 2030, growing at a CAGR of 12% from 2024 to 2030. The Warehouse Robotics Market encompasses the automation sector dedicated to developing, deploying, and utilizing robotic systems within warehouse and distribution center settings. 

👉 𝗗𝗼𝘄𝗻𝗹𝗼𝗮𝗱 𝐒𝐚𝐦𝐩𝐥𝐞 𝐑𝐞𝐩𝐨𝐫𝐭 @ https://tinyurl.com/ycxsd27c

Report Coverage

The report: “Warehouse Robotics Industry Outlook – Forecast (2024-2030)” by IndustryARC, covers an in-depth analysis of the following segments in the Warehouse Robotics industry.

By Product Type: Autonomous Mobile Robot (AMR), Articulated Robots, Cylindrical Robots, SCARA Robots, Collaborative Robots, Parallel Robots, Cartesian Robots and Others.

By Payload Capacity: less than 20Kg, 20-100Kg, 100-300Kg and greater than 300Kg.

By System Type: Knapp Open Shuttle, Locus Robotics System, Fetch Robotics Freight, Scallog System and Swisslog Carrypick.

By Components: Programmable Logic Controller, Microprocessors and Microcontrollers, Actuators, Sensors and RF Module.

By Software: Warehouse management system, Warehouse execution system, Warehouse control system and Others.

By Function: Pick & Place, Assembling & Dissembling, Transportation, Sorting & Packaging and Others.

By End-use Industry: E-commerce, Automotive, Consumer Electronics, Food & Beverages, Healthcare, Metal & Machinery, Textile, Chemical and Others.

By Geography: North America (the US, Canada and Mexico), South America (Brazil, Argentina and Others), Europe (the UK, Germany, France, Italy, Spain and Others), APAC (China, Japan, South Korea, India, Australia and Others) and RoW (the Middle East and Africa).

How are Modular Robotics Systems Revolutionizing Factory Operations?

The ballooning utilization of collaborative modular robotics systems is one of the biggest factors responsible for the expansion of the global modular robotics market. Cobots, as they are popularly called, are revolutionizing robot and human relationships in the logistics and manufacturing industries. These systems allow operators to directly provide parts and components to robots for performing the rest of the operation, which leads to reduced requirement for floor space, lower costs, and shorter process time.

Additionally, the highly versatile nature of these systems allows them to perform various tasks and operations with the help of several suitable end-effectors. In the logistics industry, cobots are used for inspecting fragile goods and transporting loads and machine parts. Because of these reasons, the sales of collaborative modular robotics systems are rising rapidly across the world. Besides this, the growing requirement for automation in the manufacturing industry is also fueling the demand for these robots around the world.

Due to the aforementioned factors, the modular robotics market is growing rapidly all over the world. The valuation of the market is predicted to rise from $5.6 billion to $15.1 billion from 2019 to 2030. Furthermore, the market is expected to progress at a CAGR of 9.9% between 2020 and 2030. Depending on robot type, the market is categorized into cartesian modular robots, articulated modular robotics systems, SCARA modular robotics systems, parallel modular robots, and collaborative modular robots.

Out of these, the articulated modular robotics systems category recorded the highest growth in the market in the past years and this trend is likely to continue in the coming years as well. This would be due to the large-scale usage of these robots for handling and managing heavy automotive components and parts in the automotive industry. In addition to this, these robots are extensively used for handling heavy metal parts and sheets in the metal and machinery industry.

The growing sales of these robots are boosting the demand for services, software, and hardware. Out of these, the demand for hardware will be the highest in the future, as per the forecast of the market research company, P&S Intelligence. Sensors, manipulators, driver modules, and controllers are the most commonly used types of hardware. Amongst these, the usage of controllers is currently the highest, because of the utilization of robot controllers in various industrial robots for accomplishing point-to-point repetitive tasks.

Geographically, the modular robotics market registered the highest growth in the Asia-Pacific (APAC) region in the years gone by. This was because of the huge investments that were made in automation in electricals, electronics, and automotive industries, particularly in countries such as India, China, and South Korea. In addition to this, the high usage of collaborative modular robotics systems by various manufacturers further propelled the advancement of the market in the region in the past.

Hence, it can be said with full surety that the sales of modular robotics systems would shoot-up all over the world in the forthcoming years, mainly because of the rising requirement for automation in various industries such as automotive, logistics, electricals, and electronics and also, in the manufacturing sector.

Source: P&S Intelligence

Petit Mal

"The formulation "an autonomous robotic artwork" marks out a territory quite novel with respect to traditional artistic endevours as we have no canon of autonomous interactive esthetics. Petit Mal is an attempt to explore the esthetics of machine behavior and interactive behavior in a real world setting. Its public function is to present visitors with the embodiment of a machine "intelligence" which is substantially itself, not an automaton or simulation of some biological system. More generally, Petit Mal seeks to raise as issues the social and cultural implications of "Artificial Life". The reflexive nature of interactivity is a focal issue: interactive behavior is defined by the cultural experience of the human visitor. As in the Turing Test, evaluation of interactivity is subjective."

Source: SimonPenny.net. (n.d.). Retrieved April 17, 2024, from https://simonpenny.net/works/petitmal.html

"Penny sought to design an interaction “in the space of the body, in which kinesthetic intelligences, rather than ‘literary-imagistic’ intelligences play a major part.” [17] Perhaps the only robot yet modeled on a form of epilepsy, Petit Mal loses motor control regularly thanks to its double-pendular body. To create a double pendulum robot that could be used safely in public was no small feat, and the odd amalgam of bicycle parts, ultrasonic and pyrosensitive sensors, and shelf-liner paper was, in Penny’s words, “an engineer’s nightmare.” He sought a robot “which is truly autonomous; which is nimble and has ‘charm’; that senses and explores architectural space and that pursues and reacts to people; that gives the impression of intelligence and has behavior which is neither anthropomorphic nor zoomorphic, but which is unique to its physical and electronic nature.” Penny described Petit Mal as “an anti-robot,” designed to avoid what he saw as the software-hardware (Cartesian mind-body) split typical in research robotics. “Hardware and software were considered as a seamless continuity, its behavior arises from the dynamics of its ‘body’.” Penny’s rejection of Cartesianism was explicitly in reference to feminist critiques of the split, and directed at negating the extreme anti-body (and to be honest: body-hating) perspectives of AI founders like Marvin Minsky or Hans Moravec."

Source: Csíkszentmihályi, C. (2022). An Engineer’s Nightmare: 102 Years of Critical Robotics (arXiv:2205.04831). arXiv. https://doi.org/10.48550/arXiv.2205.04831