8 Reasons Additive Manufacturing is Good for the Planet

| The Essentium Team


Additive Manufacturing is set to disrupt the manufacturing world in any number of ways, from faster prototyping to tool free manufacturing and mass customization. But what does this new world order mean for the planet? Here are a few reasons why we think additive manufacturing is environmentally sound.


This may be an over simplification, yes, but it is an undeniable truth. Additive manufacturing adds the material needed to make a part. Many traditional manufacturing methods, like CNC machining, are subtractive: they start with a solid piece of material and remove (or subtract) material to make a tool or part. With additive manufacturing, only the material used in the part is used in the manufacturing process. That means less waste finds its way into landfills or recycling.


Additive manufacturing is a digital process, starting with a CAD (Computer Aided Design) file that can then be sent to a printer anywhere in the world to be produced. The idea that parts can be made closer to the point of consumption is attractive economically, as well as reducing the carbon footprint of moving large numbers of parts and product around the world. As a digital process, additive manufacturing fits exceptionally well into any smart factory or industry 4.0 ecosystem; and in many ways, it is the poster child for the digital transformation of manufacturing.


One joy of additive manufacturing is the way it can create new design opportunities. This design freedom can — and often does — allow lighter parts to be designed with similar mechanical form factors and strength. Auto makers, much like aviation companies, are looking to additive manufacturing to help reduce the weight of vehicles, improving performance and reducing fuel consumption without compromising reliability or longevity.


When a product is made, spare parts are made to maintain that product in the market. These are then stored around the world in various locations to ensure they can be quickly deployed when needed. This means a huge inventory of spare parts manufactured that may never be used and may eventually have to be disposed of, often in a landfill, or recycled. In an additive manufacturing utopia, those parts are manufactured from CAD files only when they are needed. This model also allows the oldest legacy products to be supported even longer, resulting in longer product lives, less consumption and less scrap.

Imagine a world where, rather than searching for a spare part for your classic car, you can download that file from the Internet and have the part made locally on a shared 3D printing resource at Office World or the like.


Tooling is expensive and cumbersome, and it is often produced thousands of miles from production. Additive manufacturing lends itself ideally to producing cheaper tools quicker and closer to the point of use. The benefits are obvious not just in cost, but in wasted material, since many tools are made using subtractive processes like CNC machining. Tooling of this nature may also shorten time to market for a product and allow multiple iterations to occur more quickly than with traditional methods.


Deploying 3D printers in areas of consumption will, without doubt, shorten supply chains. What’s more, redesigning assemblies that would have been multiple parts from multiple vendors can reduce the vendor list and, of course, the impact and cost of transportation. The supply chain cost to the planet is significant with an alarming amount of product traveling the world’s oceans and skies at any given time. Anything that can reduce the number of supply chain miles used to make and deliver a product is both lean and green.


Much of manufacturing is done for stock or to projections and the result can be goods produced and never used, or, when a newer product is released, older stock becoming redundant. With additive manufacturing, just-in-time is much simpler, particularly in the instance of a new product release with unpredictable market demand. As additive economics change through the development of new equipment and materials, the opportunity to make at speed and scale allows brands to manufacturer to order or on-demand until product demand is more predictable.

Another benefit of manufacturing on demand is the ability to make each version unique, or to have a more fluid development from one version to the next. A new feature can simply be added to the CAD file, and the new version is introduced almost seamlessly. Some predict this will change the way product versions are currently launched, moving to a more organic approach  rather than the step-by-step iterations we’re accustomed to. This opens the doors to mass customization — considered the holy grail by many brands in a society that craves instant gratification.


The first industrial revolution was all about coal and fossil fuels producing energy. As we moved through the second and third industrial revolutions, we have been able to make manufacturing cleaner and greener. Manufacturers now look at energy consumption and emissions when choosing manufacturing methods and tools. In the age of data, we are moving to much cleaner, low-emission methods of manufacturing. Additive manufacturing is at the vanguard of that evolution.


Essentium, Inc. provides industrial 3D printing solutions that are disrupting traditional manufacturing processes by bringing product strength and production speed together, at scale, with a no-compromise engineering material set. Essentium manufactures and delivers innovative industrial 3D printers and materials enabling the world’s top manufacturers to bridge the gap between 3D printing and machining and embrace the future of additive manufacturing.


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