For many, going back to basics, and considering the underlying fieldbus technology that many of today’s digital platforms are built on, is perhaps the best first step.
It doesn’t matter whether you’re a packaging contractor running dozens of robots for pick and place applications, a busy airport operator delivering round the clock baggage handling systems or an automation giant with advanced motion control systems in place. The reality is that we all want the same thing; to run efficient, robust and often scalable networks that can increasingly handle high-volume processes, which are digitally-connected.
While the allure of smart factories and features such as remote monitoring, predictive maintenance and real-time motion control have convinced many manufacturers to take the leap of faith, they face challenges. These include complex system architectures, hardware miniaturisation, the blurring lines between ERP and MES and the need for extra hardware such as switches, hubs and network cards to make all this possible.
Rather than increase complexity, it’s advisable for business leaders and engineers to go back to basics and first consider their network from the physical, field level. While fieldbus and industrial Ethernet-based systems have been around for many years, the best ones are those that are continually and openly developed to keep up to date with the advanced needs of today’s modern, digital applications.
EtherCAT is the best example of this, and quite possibly the last fieldbus you’ll ever need. Introduced by Beckhoff in 2003, EtherCAT is a high performance, low cost industrial Ethernet that has evolved to become a globally recognised, open international standard now developed by the EtherCAT Technology Group (ETG).
What makes EtherCAT so special is that while it uses the same low-cost hardware and cabling systems of well-known Ethernet technology, it replaces the traditional TCP/IP technology stack with a real-time system that is arguably the fastest, most robust Ethernet platform on the market today.
In a network made up of a central controller (a master) connected to a series of drives or nodes (slaves) a data signal would typically be transmitted and received to and from each node, taking time to be processed by the CPU and returned to the controller.
This process uses lots of bandwidth as multiple frames of data need to be sent, received and processed. It’s also slow, as data is processed through each layer of the technology stack. EtherCAT solves this problem by taking a different approach.
With EtherCAT, a single Ethernet telegram or frame is enough to send and receive control data to and from each node. In this process, each node reads the data addressed to it and writes it back to the frame “on the fly” while the frame moves downstream.