Mitsubishi Electric has developed a cloud-based product for pro-active maintenance based on the AI platform within IBM Watson, which enables the smart analysis of operational data to predict and highlight future maintenance requirements.
The theory is that sometimes service schedule requirements for robots are inadvertently missed which, despite the extended duty-cycles and the general reliability of modern robots, is not a healthy situation for continuous plant operation. By using an innovative predictive maintenance method however, users are engaged with their robots, receive operational and maintenance data and thereby keep them healthy via planned maintenance schedules, reducing operational costs, increasing asset productivity and improving process efficiency.
Today many companies are still caught by surprise when machine failures occur. They tend to fix problems during enforced downtime, or implement preventative maintenance based on set schedules or numbers of operational hours. However, using predictive maintenance techniques production problems can be highlighted long before they result in unplanned downtime or impact on yield. Maintenance personnel can take corrective action before failure or before degraded machine performance results in sub-standard products being manufactured.
The additional benefit of predictive maintenance is that by potentially avoiding some fixed-schedule maintenance tasks you don't service equipment when it isn't required, rather on-demand, therefore saving time and expenditure.
This option from Mitsubishi Electric offering predictive maintenance for robots utilises the AI platform within IBM Watson to assess actual maintenance requirements and then suggest actions to take in an efficient and timely manner. The platform uses predictive maintenance models, digital simulation and extrapolation of trends to provide maintenance information based on actual usage and wear characteristics. This is particularly pertinent to robots, where users don't always appreciate that periodic maintenance is a mandatory requirement.
There are a number of moving parts within SCARA and articulated arm robots, depending on the type and model they include servo motors, gears, ball-screws, belts, bearings and seals. Items will experience wear over time and require eventual replacement while others will need fresh lubrication and a service check on belt tensions, etc. Considerations such as duty cycles, operating environment and loading can all play a part in dictating service requirements, so being able to visualise components with a live status and then receive considered advice tailored to that particular machine will match servicing closely to requirement.
The system also demonstrates how the speed and efficiency of any necessary maintenance activities taking place can be enhanced using voice commands. An augmented reality platform is used to create a visual overlay which provides live information in real-time interactive screen graphics. Siri, for example, can then be used to issue simple commands based on the knowledge gleaned from the screen. Increased visibility of live status information is expected to provide opportunities for significant reductions in downtime.
Using this, system maintenance activities can also be optimised through the use of smart glasses, where the operator receives guidance on what tasks need to be performed. The glasses can show CAD drawings of the various robot parts, superimposed over the robot itself. The glasses can also show the maintenance manual and individual instructions.
This type of next generation human / machine interaction works well with the latest safety systems that can do away with the traditional interlocked cage in many instances, relying on smart proximity sensors and Mitsubishi Electric's MELFA SafePlus feature to manage robot movement safely in the presence of humans.
For more information about pro-active maintenance of industrial robots please visit gb3a.mitsubishielectric.com.