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Embracing series production in additive manufacturing

Jun 22, 2023Jun 22, 2023

By Rachael Pasini | May 30, 2023

Evolving from prototype and small-batch production to series production of plastic and metal parts in additive manufacturing increases efficient utilization of 3D printing equipment, provides a safe working environment, and creates an optimal production flow. Achieving efficient series production, however, requires intelligent automation and networking capable of perfectly integrating long production times of components in 3D printing with shorter upstream and downstream steps.

By Oliver Elbert, Head of Additive Manufacturing • Grenzebach Group

Additive Manufacturing (AM), or 3D printing, is the manufacturing of a three-dimensional object from a CAD model or a digital 3D model. It can be done in a variety of processes in which material is deposited, joined, or solidified under computer control with material being added together (such as plastics, liquids, or powder grains), typically layer by layer.

Thirty-five years ago, 3D printing techniques were considered suitable only for the production of functional or aesthetic prototypes. As of the past several years, however, the precision, repeatability, and material range of additive manufacturing has increased to where it is now a viable industrial-production technology.

Because additive manufacturing is a material joining process, whereby a product can be directly fabricated from its 3D model, usually layer upon layer, it delivers considerable advantages compared to traditional manufacturing technologies such as CNC machining or casting. Additive manufacturing processes have the unique capability of enabling the fabrication of parts with a complex shape as well as complex material distribution, and significantly enlarges the design freedom for designers.

The challenge with additive manufacturing is the long production time required for each item in the 3D printer, whereas upstream and downstream production steps have significantly shorter lead times. This makes for considerable inefficiencies in the overall additive manufacturing process.

The solution is series production, with intelligent automation and network integration of all upstream and downstream processes in the 3D printing cycle. Users benefit from automated processes, while ensuring optimum material flow between individual devices such as printers, depowdering and finishing systems. In addition to increasing efficient utilization of the 3D printing equipment, automated production provides a safe working environment for workers.

Improved efficiency. Automation intelligently and reliably networks process steps with different throughput times. 3D printing, pre-processing and post-processing systems are mechanically, electronically, and digitally synchronized, resulting in optimally utilized machinery with maximum output.

Lower cost per part. Intelligent networking of the individual working steps allows maximum use of all systems. This enables production with lower costs per part.

Occupational health and safety. During the post-processing of 3D-printed components, there may be health risks due to fine dust and nanoparticles. Optimally designed automation solutions comply with occupational health and safety regulations and reduce risks for workers.

Multiple process steps of varying duration make additive manufacturing a complex matter. Each manufacturer has specific requirements for type of material being used for 3D printing, preprocess, and postprocess procedures. To prepare a sequence of 3D printing functions for streamlined serial production requires addressing the automation components for each process.

Following is a breakdown of automated system solutions that support intelligent synchronization of series production for additive manufacturing. These systems cover loading and unloading, additive manufacturing, depowdering, and postprocessing:

Additive manufacturing opens up new perspectives for so many industries, but the automotive and aerospace industries have been early embracers of this critically important technology. For the production of components, these industries are increasingly capitalizing on the possibilities of additive manufacturing.

Vehicles and aircraft can be designed with fewer components but with enhanced functionalities and lower overall weight. Intelligent automation and networking are required for safe, efficient series production of components by 3D printing.

In particular, the synchronization of production steps and transport between manufacturing cells, as demonstrated in series production, is immensely important. Good capacity utilization is key. Only in this way can the equipment be used optimally with long production times of a build job in the printer and significantly shorter throughput times of upstream and downstream production steps.

Because so many factors can impact additive manufacturing processes, it is important for manufacturers to consult an experienced 3D printing automation expert who knows the specifics and priorities influencing series production relative to their application. This is necessary for analysis of requirements and optimum concept development, to ensure the smooth integration into the production environment, including the integration of existing machines into the process chain. Automation experts help manufacturers develop solutions to facilitate achieving the desired production throughput and process control, while ensuring maximally efficient use of 3D printing equipment.

Grenzebachgrenzebach.com

Evolving from prototype and small-batch production to series production of plastic and metal parts in additive manufacturing increases efficient utilization of 3D printing equipment, provides a safe working environment, and creates an optimal production flow. Achieving efficient series production, however, requires intelligent automation and networking capable of perfectly integrating long production times of components in 3D printing with shorter upstream and downstream steps. Improved efficiency. Lower cost per part. Occupational health and safety. Robot cells Transportation and conveying equipment Machine fitting Inspection Software integration Grenzebach