Erfahren Sie mehr über den allgemeinen additiven Herstellungsprozess vom Design bis zum fertigen Teil für diejenigen, die noch nie zuvor in 3D gedruckt haben.
Additive manufacturing (often referred to as rapid prototyping or 3D printing) is a method of manufacturing where layers of material are built up one at a time to create a solid object. While there are many different additive manufacturing and 3D printing technologies out there, this article will focus on the general process from design to the final part.
Whether the final part is a quick prototype or an end-use functional part, the general process does not change significantly. Let's get into it.
Producing a digital model is the first step in the additive manufacturing process. The most common method for producing a digital model is by using computer-aided design (CAD). There is an extensive range of free and professional CAD programs that are compatible with additive manufacturing technologies. Reverse engineering can also be used to generate a digital model via 3D scanning.
There are several design considerations that must be evaluated when designing digital models for additive manufacturing. These generally focus on feature geometry limitations and support or escape hole requirements, to name a few. Factors like these tend to vary by technology, so it’s essential to brush up on them.
A critical stage in the additive manufacturing process that varies from traditional manufacturing is the requirement to convert a CAD model into an STL (stereolithography) file. STL uses triangles (polygons) to describe the surfaces of an object. A guide on how to convert a CAD model to an STL file can be found here.
There are several model limitations that should be considered before converting a model to an STL file, including the model’s physical size, water tightness and polygon count.
Once an STL file has been generated, the file is imported into a slicer program. This program takes the STL file and converts it into G-code, a numerical control (NC) programming language. It’s used in computer-aided manufacturing (CAM) to control automated machine tools (including CNC machines and 3D printers). The slicer program also allows the designer to customize the build parameters including supports, layer height, and part orientation.
Additive manufacturing machines (3D printers) comprise many small and intricate parts so correct maintenance and calibration are critical to producing accurate prints.
The raw materials used in additive manufacturing often have a limited shelf life and require careful handling. While some processes offer the ability to recycle excess build material, repeated reuse can reduce material properties if not regularly replaced.
Most additive manufacturing machines don’t need to be monitored after the print has begun. The machine will follow an automated process and issues generally only arise when the machine runs out of material or there is an error in the software. An explanation of how each of the different additive manufacturing printers produces parts can be found here.
For some additive manufacturing technologies removal of the print is as simple as separating the printed part from the build platform. For other more industrial 3D printing methods the removal of a print is a highly technical process involving precise extraction of the print while it is still encased in the build material or attached to the build plate.
These methods require complicated removal procedures and highly skilled machine operators along with safety equipment and controlled environments.
Post-processing methods vary by printer technology. SLA requires a component to cure under UV before handling, metal parts often need to be stress relieved in an oven while FDM parts can be handled right away. For technologies that utilize support, this is also removed at the post-processing stage. Most 3D printing materials are able to be sanded and other post-processing techniques including tumbling, high-pressure air cleaning, polishing, and coloring are implemented to prepare a print for end use.
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There are seven technologies under the additive manufacturing umbrella. These are vat polymerization, material extrusion, material jetting, sheet lamination, directed energy deposition, binder jetting and powder bed fusion.
The terms additive manufacturing and 3D printing are, for the most part, interchangeable. Both refer to manufacturing processes where parts are built up layer by layer from a CAD design.
While additive manufacturing and 3D printing are often used interchangeably, rapid prototyping is a related but distinct process. Rapid prototyping refers to the accelerated prototyping stage of product development, with additive manufacturing being a process to support that aim.
Additive manufacturing is used across a huge (and growing) range of industries, including aerospace, robotics, consumer electronics and automotive. One industry that’s benefitted immensely from the advent and widespread adoption of additive is medical technology. Historically, most industries have tended to use additive for prototyping, but with more robust technologies coming into the market, companies are turning to additive for end-use parts and higher volume production as well.
Additive manufacturing comes with many unique advantages. It’s a much more cost-effective way to create prototyping parts than subtractive processes, and it produces less material waste. The cost of entry is quite low and it’s cheaper for smaller and faster for production runs. Additive manufacturing is especially useful if you have to recreate legacy parts that you want to optimize.
Additive manufacturing can create custom parts using polymers, metals and, in some cases, ceramics. The most common material you’ll see in additive manufacturing is plastic, especially for prototyping.
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Erfahren Sie mehr über den allgemeinen additiven Herstellungsprozess vom Design bis zum fertigen Teil für diejenigen, die noch nie zuvor in 3D gedruckt haben.
Weiterlesen
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What 3D printing process is optimal for prototyping? This article explores the best 3D printers for the prototyping phase of product development, including design advice to get the most out of each manufacturing technology.
Weiterlesen
Interested in learning the basics of FDM 3D printing? In this article, we explain why this technology is an efficient and cost-effective choice for rapid prototyping and other applications.
Weiterlesen
Is 3D printing or CNC machining better for your custom part applications? Learn the practical differences between CNC machining and 3D printing and how to select the right technology for manufacturing prototypes, end-use parts and everything in between.
Weiterlesen
What are the different types of 3D printers available for manufacturing today and what are their unique characteristics and capabilities? This article examines the main additive manufacturing technologies and goes into detail about every major 3D printing method.
Weiterlesen
In diesem Artikel werden die Hauptvorteile des 3D-Drucks im Vergleich zu traditionellen Fertigungstechniken erörtert.
Weiterlesen
Erfahren Sie mehr über den allgemeinen additiven Herstellungsprozess vom Design bis zum fertigen Teil für diejenigen, die noch nie zuvor in 3D gedruckt haben.
Weiterlesen
Erfahren Sie, was eine 3D-Druck-Abstützungsstruktur ist, wann Abstützung benötigt wird und wie sich diese auf die Qualität und den Preis Ihres Drucks auswirken kann.
Weiterlesen
Erfahren Sie, was sich auf den Preis von gedruckten 3D-Teilen auswirkt und wie der 3D-Druck erschwinglicher gemacht werden kann.
Weiterlesen
