Many manufacturers are either implementing or considering implementing some version of Industry 4.0 and/or 3D printing into their operations. So, where are we and where are we going? The 3D printing experts at Markforged offer their thoughts.
Professional 3D printers today use augmentative technologies -- such as cloud connectivity, data analytics, automation, and software integrations -- to help manufacturers leverage each printer in new and innovative ways.
An accessible way to go from design to metal part -- Markforged's Metal X System is a leading end-to-end additive manufacturing solution.
The addition of these technologies into professional 3D printers is part of the digital transformation of manufacturing, commonly known as Industry 4.0. So what is the role of today's professional 3D printers in Industry 4.0? What are some examples of how additive manufacturing platforms use Industry 4.0 technologies to provide solutions for problems?
Defining Industry 4.0
McKinsey & Company defines Industry 4.0 as a name for the broader "digitization of the manufacturing sector" -- what this translates to more specifically is the application of emerging technologies into manufacturing facilities to improve processes.
Key themes and characteristics of Industry 4.0 include:
Specific technologies that have fueled Industry 4.0 include cloud computing, artificial intelligence (AI), the industrial Internet of Things (IoT), data analytics, industrial robotics systems, professional 3D printers, and big data.
Professional 3D printers today are connected to users and other 3D printers through the cloud. As a result, print jobs can be monitored and initiated across different geographic locations.
While these individual technologies were not developed for the express purpose of use in smart factories, Industry 4.0 describes the growth and maturation of their application to factory settings.
The Relationship Between Industry 4.0 and Additive
Additive manufacturing is a technology native to Industry 4.0. Converting digital inputs to physical outputs, digital inventory in the form of CAD files is uploaded to 3D printer software, resulting in conversion from the digital object to a physical equivalent.
Essentially, it's an enabler for the core suite of Industry 4.0 technologies -- such as cloud computing, smart automation, IoT devices, digital inventory, and data analytics -- to be directly applied to the process of fabrication itself.
While previously this was only applicable to select, less demanding applications, the expansion of professional 3D printer technologies -- such as broadened material offerings in both composites and metals, as well as substantial improvements to speed, reliability, accuracy, and quality -- allow it to comfortably digitize manufacturing processes for a far wider breadth of applications, and on a larger scale than before.
Adoption rates of additive manufacturing technologies across industries.
In a way, 3D printing is the specific technology most emblematic of Industry 4.0: amongst the list of individual technologies that collectively shape it. 3D printing is the only one that holistically applies the defining characteristics to the actual fabrication of parts.
While the capabilities of professional 3D printers have helped shape Industry 4.0, many Industry 4.0 technologies have also fueled the growth of additive manufacturing.
When first introduced, professional 3D printers were naught but individual hardware items. Additive manufacturing has since grown with Industry 4.0, into today's full-fledged 3D printing platforms with advanced 3D printing software capabilities, connectivity to devices in disparate geographical locations, a wide range of advanced analytics, and AI-driven automated features such as autonomous part inspection.
Examples of How 3D Printers Use Industry 4.0 Technologies
To enable manufacturers to get the most out of each professional 3D printer, additive manufacturing solution providers have integrated the core set of Industry 4.0 technologies into their 3D printer platforms.
3D printed cockpit console and cupholders for aircraft
Here are examples of the technologies, how they augment professional 3D printers, and how they solve problems for manufacturers:
Cloud computing provides connectivity between users and every professional 3D printer operated by an organization, across disparate geographic locations. Effectively, a user can hop on their laptop and initiate printing of a repair part for a factory halfway across the globe.
With a digital inventory of parts as data items stored in the cloud, this ability confers numerous benefits: manufacturers can avoid the need to stock up on large amounts of inventory, and effectively operate with a lean manufacturing model with just-in-time (JIT) production.
Furthermore, a distributed manufacturing model allows users to avoid supply chain complications and simply get parts faster, by printing parts to the exact point of need when they are needed, as opposed to submitting an order for a part to be created at one location and having it shipped to the point of need.
3D printer software with automated, AI-driven part inspection.
Software for today's professional 3D printers also provide various data analytics for their users.
Organizations can track metrics such as material usage, print job quantities per user according to time intervals, printer bandwidth per user, parts uploaded per week, and custom analytics fields. Print times and costs per print job are calculated according to variables such as part size, material, and volume of fiber used to reinforce the plastic matrix. Using these analytics can allow organizations to understand usage patterns of equipment and optimize resources accordingly.
Professional 3D printers are inherently automated by nature -- simply hitting the "print" button will take you from art to part in just hours to days without the need for hands-on work, management, or human oversight. With in-house additive manufacturing, engineers do not have to worry about time-consuming procurement activities like drafting drawings, submitting purchase orders, and managing the bidding process with multiple vendors.
More recently, quality inspection of parts has been fully automated -- during the fabrication process, AI-powered 3D printing software can verify that a printed part is immediately usable in the factory, automatically generating part quality and traceability reports.
VIDEO: Metal 3D Printing Walkthrough | Markforged Metal X
Through 3D printing software APIs, professional 3D printers can also integrate with other core systems within a smart factory, such as through a Manufacturing Execution System (MES), Enterprise Resource Planning (ERP) or Enterprise Asset Management (EAM) system. Print jobs can be initiated through any of these systems. If a user requests a part in one of these systems, that system can trigger an automatic print job in any specific 3D printer.
What Does This Mean for Manufacturers?
Through the integration of Industry 4.0 technologies, AM has allowed manufacturers to connect their manufacturing across geographic locations, enable a lean manufacturing model with the accessibility of a digital inventory, and automate a lot of the arduous tasks that come with part fabrication.
As professional 3D printer technologies continue to develop, digitization through Industry 4.0 technologies can be expected to reach an even wider range of digital manufacturing applications.
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