By Jan Irzyk, AIMS Product Manager at ANCA CNC Machines
The tool manufacturing industry is embracing automation solutions at an unprecedented pace. This is a worldwide trend driven by several factors - labor shortage, increasing labor costs, the need for maximizing uptime, push for 24/7 machine availability, and customers demanding shorter lead times. Manufacturers need to be more flexible and responsive than ever before.
ANCA has been providing a wide range of automation solutions for many years. One of the recent offerings in this space is our ANCA Integrated Manufacturing System, or AIMS for short. AIMS is an ecosystem of individual modules – or building blocks - which could be configured to build a tailored automated tool manufacturing system.
Modularity and flexibility mean that it caters to both small and large enterprise-type manufacturers. The system could be designed to be very simple, using a trolley for manual pallet and tool transfer with basic ERP connectivity. It could also be a complex, fully autonomous production solution which requires minimal human intervention.
One of the most noticeable components of a fully automated AIMS cell is AutoFetch – the AMR robot responsible for transferring pallets between the setting station called AutoSet, to the tool grinder. It also automatically transfers single tools for spot-check measurements outside of the grinder.
As you can imagine, there’s a lot of traffic and the AutoFetch can get very busy. An AIMS cell is typically configured within a footprint of the existing factory with adjoining areas where standard, manual operations are taking place. This is a great flexibility feature but also raises many questions about how autonomous operation can function alongside the traditional production plant with frequent foot traffic.
There’s no need to fence off the AIMS area thanks to the unique technology used with the AutoFetch robot. There are generally two types of automatic vehicles used on the factory floor – AGV and AMR. AutoFetch is an AMR (Autonomous Mobile Robot) which is different from AGV (Automatic Guided Vehicle). The main difference is the way both units navigate their way around the factory. An AGV always follows a predetermined route which is defined by using various guiding aids like strips embedded in the floor, or reflectors fitted to the walls around the route.
The AMR on the other hand, travels from one location to another using its array of sensors and initially scanned map of the area. It doesn’t require any additional infrastructure to transfer material from A to B. You just scan and map the relevant area during AutoFetch setup, mark the load and unload positions and then the robot, using sophisticated algorithms, will find the optimal way from one point to the other.
Autonomous material transfer
One of the most common questions we’re being asked is related to safety of the AutoFetch. This is understandable since AutoFetch operates alongside personnel in the factory. The good news is the AutoFetch AMR is designed to safely operate in a factory environment where people are present. The AMR moves from one station to another using an optimized route, and it constantly scans the immediate area for unexpected objects.
When an object is detected, AutoFetch will stop and navigate around it. An array of sensors - laser scanners, 3D cameras, and proximity sensors - are used for this purpose. For extra security, an AMR-prohibited area could be defined on the map to exclude autonomous traffic altogether. In addition, AutoFetch could be programmed to reduce speed in certain areas and warn nearby staff with audio warnings such as beepers, horns, or pre-recorded spoken messages.
Seventy-two percent of manufacturers report accidents related to using traditional means of material transport like pallet jacks, trolleys or forklifts. The use of AMRs contributes to increased safety in the factory and reduced accidents due to the elimination of human factors like fatigue, lack of focus or awareness.
Jan Irzyk is currently focused on ANCA Integrated Manufacturing System (AIMS ). He is driving the expansion of the ANCA portfolio with the idea of helping tool manufacturers maximize their outcomes and face current challenges.
Related Glossary Terms
- computer numerical control ( CNC)
computer numerical control ( CNC)
Microprocessor-based controller dedicated to a machine tool that permits the creation or modification of parts. Programmed numerical control activates the machine’s servos and spindle drives and controls the various machining operations. See DNC, direct numerical control; NC, numerical control.
- fatigue
fatigue
Phenomenon leading to fracture under repeated or fluctuating stresses having a maximum value less than the tensile strength of the material. Fatigue fractures are progressive, beginning as minute cracks that grow under the action of the fluctuating stress.