Industrial robots: A game changer in the manufacturing sector

The quest to increase manufacturing agility and reduce production costs has given rise to a new breed of machines – industrial robots. Industrial robots can perform a range of repeatable tasks with precision, speed, and consistent quality.

As a result, they are highly coveted in automotive, electronics, metals, chemicals, and food manufacturing industries. Worldwide sales of industrial robots hit record highs in 2017 and is expected to increase by at least 15 percent on average per year until 2020, signaling the rapid transition towards Industrial 4.0. We took a closer look at this emerging trend in the manufacturing sector.

Industrial robotics offer significant advantages for SMEs and large manufacturers alike. Most industrial robots are standardized and offer intuitive programming methods. As a result, they are easy to use and help ensure consistency and accuracy in manufacturing processes such as soldering, material handling, cutting, drilling, assembling and polishing, among others.

The key factors that are driving the expansion of robot usage in industrial processes include:

  • The rapid expansion of industrial activities that operate on the basis of increased efficiency, reduced human errors and improved worker safety.
  • A dearth of skilled workers, which has driven up labor costs.
  • Decreasing prices of robotic devices. The last 30 years have seen average robot prices fall by about half.
  • Technological advances in software and networking technology that have simplified the process of assembling, installing and maintaining robots both in terms of effort and cost.

As per the International Federation of Robotics, robots are classified only based on mechanical structure.

Articulated Robots: This robot design features rotary joints and can range from simple two joint structures to 10 or more joints. These are typically used in the handling of metal casting, palletizing, welding, and painting.

SCARA Robots: Commonly used in assembly applications, this selectively compliant arm for robotic assembly is primarily cylindrical in design. SCARA robots are typically used in assembly and packaging functions.

Linear/ Cartesian Robots: These are also called rectilinear or gantry robots. Cartesian robots have three linear joints that use the Cartesian coordinate system (X, Y, and Z).

Primarily used in:

  • Laser Welding
  • Pressing
  • Sealing
  • Handling of Plastic Moulding

Parallel Robots: These spider-like robots are built from jointed parallelograms connected to a common base. Heavily used in the food, pharmaceutical, and electronic industries to carry out functions such as picking and placing, assembly, and handling.

Polar: Also called spherical robots, in this configuration, the arm is connected to the base with a twisting joint and a combination of two rotary joints and one linear joint.

Primarily used for:

  • Picking and Placing
  • Assembly
  • Handling

Cylindrical: The robot has at least one rotary joint at the base and at least one prismatic joint to connect the links.

The articulated robots segment accounted for the maximum share in the global industrial robotics market in 2016, owing to their extensive use in the packaging and healthcare sectors. Based on functionality, materials handling sub-segment holds the maximum share.

Most robotics operating systems have been developed due to research initiatives by universities or industry leaders. It’s not uncommon for such platforms to be open-source, enabling developers to make modifications that enhance the capabilities of systems.

Intelligent Robot software Platform (iRSP): iRSP is an open platform by Bonavision, Inc., that enables the development of intelligent robots.  The most important characteristics of iRSP are its capabilities of integration and support for artificial intelligence.

ROS Industrial (ROS-I): ROS-I is an advanced open-source robotics software, which extends the capabilities of Robot Operating System (ROS) software to manufacturing. ROS-I provides some key benefits to the industrial robotics industry such as interchangeability of hardware components, standardized access to applications, and manufacturer-independent drivers.

VxWorks: VxWorks is a real-time operating system (RTOS) used in many of the industrial robots manufactured by ABB, Kuks, Stäubli, and Yaskawa Electric Corporation.

NAOqi OS: NAOqiOS is the operating system that manages SoftBank’s humanoid Nao robots.

Industrial robot manufacturers have delved into research and production operations aimed at developing mobile robots and co-bots for the purpose of upgrading the capabilities and applicability of such robotic devices.

ABB: Offers industrial robots, such as IRB 14000, YuMi®, controllers such as IR5 series, application equipment, such as arch welding robotic system,  and manufacturing solutions.

Fanuc robotics: Has more than 100 models of industrial robots (e.g., M-710 Series using AGT Robotics Self-Learning Technology). Offers CNC systems (i.e., controllers, drives, motor and laser systems) and app-based robots such as robodrills and robocuts.

Yaskawa: Offers a variety of industrial robotic products for application areas including handling/mounting, welding/cutting, packaging/palletizing and painting. Products include SIA20D/SIA20F, a seven-axis actuator-based design using ROS interface, human-collaborative HC10 bots, mobile robots, among others.

Kuka: Provides intelligent automation solutions and innovative collaborative industrial robots, such as LBR IIWA, which can work in collaboration with humans based on KUKA Sunrise control technology, and app-based robots such as six-axis palletizing robots and welding robots.

Omron: Offers industrial robots for high-speed, precision manufacturing, packaging, and factory automation.  Products include an expansive line of Cobra SCARA robots, Viper six-axis (articulated) robots, Quattro parallel robots, and Python linear modules

The industrial robotics space is an interplay between the companies manufacturing industrial robots and other related equipment, companies developing manipulation software to enhance the capacity of the robots, system integrators and, lastly, the OS platform developers, which forms the core of these robots.


According to industry reports, investors spent 50% more in 2016 than they did in 2015 on robotics start-ups. The key areas of industrial robotics investment, include unmanned aerial vehicles, self-driving cars, and robots in agriculture and healthcare. Despite the high growth potential, however, industrial robotics players face challenges such as high barriers to entry, high initial investment, and safety issues.

To say that industrial robotics hold the key to the future of manufacturing is a redundant statement. Robots are here and are actively being incorporated in day-to-day business operations. Robots are even beginning to interact with customers in increasing numbers. While ethical conundrums might emerge, the implications of industrial robotics are undeniably vast and are fast becoming immediate.

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