(IME 2022/2023 - 2ª fase)
NAS QUESTÕES DE 33 A 39, RESPONDA DE ACORDO COM O TEXTO 2.
Text 2
Overview of current additive manufacturing technologies and selected applications
Horn, T..J. e Harrysson, O.L
1 | Three-dimensional printing or rapid prototyping are processes by which components are fabricated directly |
from computer models by selectively curing, depositing or consolidating materials in successive layers. These | |
technologies have traditionally been limited to the fabrication of models suitable for product visualization but, over | |
the past decade, have quickly developed into a new paradigm called additive manufacturing. | |
5 | It remains to be seen what the long term implications of additive manufacturing will be. In many regards, it is |
a technology that is still in its infancy and it represents a very small segment of manufacturing overall. That small | |
segment is growing quickly but the future is by no means certain. Scarcely a quarter century has passed since | |
the first stereolithography systems for rapid prototyping appeared on the market. | |
In that short time, additive manufacturing has not only become relatively common place in science, academia, | |
10 | and industry, but it has also evolved from a method to quickly produce visual models into a new manufacturing |
paradigm. In the past two decades, revenues associated with products and services show that additive manufac- | |
turing has grown into a multi-billion dollar industry | |
Additive manufacturing has the potential to radically change the way in which many products are made and | |
distributed. Throughout history, key innovations in manufacturing technology have had a profound impact on our | |
15 | society and our culture. An examination of the applications and technologies suggest that additive manufacturing |
may become a truly disruptive technology. | |
Prior to the industrial revolution goods were typically produced by skilled artisans and were often tailored | |
to satisfy a specific, individual demand. While this approach may have had many inherent advantages to the | |
consumer (i.e. high quality, custom parts on demand) it is doubtful that system could have persisted under the | |
20 | growing demands of society. |
The invention of the first machine tools (that is tools capable of precisely controlling the relative motion | |
between a tool and a work piece) along with advances in fixturing and metrology facilitated the manufacture | |
of interchangeable parts which, in turn, supported the development of the mass production system. The model of | |
mass production also has many clear advantages to both the producers and the consumers of products, including; | |
25 | high throughput, high quality and product consistency at a low unit cost. This, of course, comes at the cost of |
reduced product diversity. | |
In the last century, the means by which many goods are manufactured has been radically enhanced by | |
computer controlled machinery and automation. However, in general, the basic methods and materials are quite | |
similar to those used at the turn of the 19th century. Bulk materials must still be either cut, formed, or molded in | |
30 | order to fabricate value-added products. In fact, a large portion of the products that we consume or use at the |
present time are manufactured using processes like forming, injection molding, casting, extrusion, stamping, and | |
machining. Each one of these processes requires some form of tooling (mold, die, flask, stamp, fixture, etc.). | |
For instance, if we consider casting an exhaust manifold in steel we must first design and fabricate a sand or | |
investment mold with the negative shape of the final part. A metal stamped part, as simple as a washer, requires | |
35 | a die and a large stamping press in order to be produced. A simple plastic cover for a smart phone requires an |
injection mold that may cost thousands of dollars and an injection molding machine that may costs hundreds of | |
thousands to millions of dollars. The cost and time dedicated to the design and fabrication of tooling that supports | |
mass production represents a significant percentage of the total cost of a product. | |
The natural result of high tooling costs is that within a given mass production system there is an inverse | |
40 | relationship between the quantity of a product that is produced and the variety of product designs available. |
It is necessary that we recognize that production tooling is not only expensive, but it also constrains the | |
design of products based on innate limitations imposed by the various mass production processes. This is a | |
widely studied area of manufacturing known as design for manufacture (DFM). | |
As a brief example, consider a plastic injection molded part. One of the key limitations is that the mold must | |
45 | provide for the easy removal of the part. This means that the part must have slightly outward sloping surfaces |
(called positive draft), as inward sloping surfaces would essentially lock the part to the mold like a dovetail making | |
it impossible to remove. Further, the injection mold itself must be precisely machined, ground, and polished from | |
a block of metal, and the processes that are used to do that, like milling with a cutting tool, also have similar | |
limitations (i.e. the cutting tool must be able to access the feature that will be cut). | |
50 | Increasing the complexity of the part to better serve a given function can drive up the cost of the tooling |
required for producing it and, in many cases, the optimal design for a given purpose is impossible to produce | |
using traditional mass production methods | |
Additive manufacturing represents a fundamentally new method of part fabrication. It is the process of | |
fabricating components directly from 3D computer models by selectively depositing, curing, or consolidating | |
55 | materials one layer upon the next. Each layer represents the cross-sectional geometry of the part at a given |
height. This is a stark contrast to traditional manufacturing processes like forming, casting, and machining | |
because tooling is not required to produce a part. The freeform nature of additive manufacturing is therefore | |
changing the way we look at traditional DFM constraints. In many cases the traditional constraints no longer | |
apply. | |
60 | By building parts additively, in layers, components can be manufactured with extremely complex geometries, |
such as internal channels, undercut features, or engineered lattice structures with controlled and/or variable | |
porosity. These are features that are extremely difficult or impossible to produce with traditional methods. | |
The implication of this is quite simple to recognize but at the same time has a profound result. Removing the | |
need for tooling facilitates the economical production of small lot sizes of parts (as low as one) without sacrificing | |
65 | interchangeability, thereby reducing the lead time for production (because the tools do not need to be produced), |
allowing flexibility in the supply chain and the production location (parts can be made where and when they | |
are demanded), and raising the possibility of transitioning from a system of mass production to one off mass | |
customization. It also means that design changes incur much less cost in production so products can potentially | |
be customized to conform to the needs of the individual consumer. In many ways this concept goes far beyond | |
70 | the definition of most existing mass customization models in which mass produced components are fabricated |
and then assembled on demand to specific customer orders. |
Adapted from: Sage Journals. Available at: <https://journals.sagepub.com/doi/abs/10.3184/003685012X134209844630>[Accessed on 10th March 2022].
Choose the correct option.
Additive manufacturing is the process of fabricating models by depositing materials in successive layers.
Production based on tooling may be cheap but it is not adequate for mass production.
The use of tools in additive manufacturing simplifies part fabrication.
Additive manufacturing may replace mass customization with mass production.
Complex parts are more easily made with additive manufacturing than with traditional methods.