Additive Manufacturing is the peer-reviewed journal that provides academia and world-leading industry with high quality research papers and reviews in additive
10.02.4.1 Advantage: Freedom from Manufacturing Constraints. Additive manufacturing enables the creation of parts and products with complex features, which could not easily have been produced via subtractive or other traditional manufacturing processes.
Additive manufacturing (AM), often referred to as rapid prototyping, freeform fabrication, or 3D printing, is defined as "the process of joining materials to make objects from 3D model data, usually layer upon layer, as opposed to subtractive manufacturing1, 2].
Comprehensive additive manufacturing (AM) overview: concepts, processes, materials, pros, and cons • Recent AM advances: multi-material, large-scale
Take a look at the top 10 advantages of additive manufacturing. 1. Cost Of Entry Continues to Fall. You might think that diving into any new manufacturing method demands a big upfront capital investment, but with additive manufacturing, that isn''t necessarily true. The cost of entry for AM has consistently been falling.
The antenna''s main characteristics were optimized with a gain of 27.7 dB and a −3 dB main-lobe beamwidth. A wide range of materials for additive manufacturing, including conductive materials, can be utilized to create conductive structures within the The 3D
Additive manufacturing, also known as 3D printing, is a cutting-edge manufacturing process revolutionizing industries worldwide. It involves building objects
In today''s era, additive manufacturing (AM) is attracting unparalleled attention across the globe. From initial obscurity, today there is practically no sphere of life untouched by this technology. The quantum of research in this field has witnessed overwhelming growth which in turn leads to impressive newer developments at almost
The application of additive manufacturing ultimately relies on the process and resultant material meeting properties and characteristics that are established during design. In this regard, the process is defined as the selection of a material that when paired with an
Traditional gas tungsten arc-based additive manufacturing (GTA-AM) system normally applies high-level deposition current to achieve a high deposition rate. Due to the induced high arc pressure, defects (e.g., humps) may always happen, which made the deposited beads unsuitable for additive manufacturing (AM) purposes. To solve this
Over the past few decades, additive manufacturing (AM) has become a reliable tool for prototyping and low-volume production. In recent years, the market share of such products has increased rapidly as these manufacturing concepts allow for greater part complexity compared to conventional manufacturing technologies. Furthermore, as
Additive manufacturing (AM) also known by other names as well such as three-dimensional (3D) printing, layered manufacturing (LM), rapid prototyping (RP), and solid freeform fabrication (SFF) is a
Nowadays, the implementation of additive manufacturing (AM) is rapidly growing in various sectors. Many manufacturing industries are demanding an increase in the size of the AM parts. Wire arc additive manufacturing (WAAM) offers a high deposition rate and quality products without size limits. The welding process of gas tungsten arc
Titanium alloy Ti6Al4V manufactured by additive manufacturing (AM) is an attractive material, but the fatigue strength of AM Ti6Al4V is remarkably weak. Thus, post-processing is
Additive manufacturing refers to the fabrication of three-dimensional products by adding materials layer by layer to get the required shape and size. Although there are numerous additive manufacturing processes available based on the type of feedstock used, the powder-based additive method is the most popular technique as it is
One of the most promising manufacturing processes for producing complex geometries in a shorter amount of time is additive manufacturing. However, the majority of additively manufactured industrial components fail to meet their intended specifications. The surface quality achieved by additive manufacturing parts is one of
Fig. 1 describes the various stages of additive manufacture to produce the end-use part. Based on the layer of material, AM manufacturing is categorized into different groups, including: • Photopolymerization • Material jetting • Binder jetting • Material extrusion •
Due to its multifaceted features, time and price savings, Additive Manufacturing performs a significant part in Industry 4.0, being critical to process
Introduction Additive manufacturing (AM), also known as three-dimensional (3D) printing, has been identified as one of twelve disruptive technologies that comprise the fourth industrial revolution (Industry 4.0)
Roughness affects the mechanical behavior of products like wear resistance, crack initiation, bearing, fatigue life, sealing, mating, and fluid dynamics. There are two kinds of strategies of the AM process that can be used to enhance the surface characteristics of the AM parts: 1. Pre-processing. 2.
Additive manufacturing (AM) also known by other names as well such as three-dimensional (3D) printing, layered manufacturing (LM), rapid prototyping (RP), and solid freeform fabrication (SFF) is a novel method of manufacturing that builds three-dimensional parts layer upon layer using computer-aided designing (CAD) data.
With the growing interest in 3D printing, many studies are being conducted to replace conventional manufacturing processes. In terms of mechanical applications, however, research on the tribological characteristics of 3D printing components has not been sufficiently conducted. This study investigated the influences of surface texturing
Antennas play a critical role in modern technology. They are used in various devices and applications, including wireless communication, broadcasting, navigation, military, and space. Overall, the importance of antennas in technology lies in their ability to transmit and receive signals, allowing communication and information transfer
Additive manufacturing (AM) technologies are rapidly enabling flexible production in the industries with digitalization and automation in processes. The unique features of this technology are lesser lead time, design customization, and limited use of tooling as compared to conventional manufacturing techniques.
To additive manufacturing newcomers, material extrusion AM processes are likely to be the most recognisable, interchangeably referred to as FDM (Fused Deposition Modelling) or FFF
Additive manufacturing is an umbrella term for the production methods in which three-dimensional objects are built from digital files in a computer-controlled
Additive manufacturing refers to the set of technologies that allow the manufacture of objects in a sequential manner, usually layer by layer. It
The international standard ISO/ASTM 52900 defines additive manufacturing (AM) as a "process of joining materials to make parts from three
Design flexibility, mass customization, minimization of waste and the capacity to produce complicated constructions are the primary advantages of additive manufacturing. The present situation of growth of 3DP products involves, among many others, concrete [], the use of wood, metal alloys, metal composites, polymer composites,
Polishetty A, Raju B, Littlefair G. Secondary machining characteristics of additive manufactured titanium alloy Ti-6Al-4V. Key Eng Mater 2018; 779: 149–152. Crossref Google Scholar 19. Khanna N, Zadafiya K, Patel T,