Rapid Manufacturing | ScienceGate

High requirements imposed by the competitive industrial environment determine the development directions of applied manufacturing methods. 3D printing technology, also known as additive manufacturing (AM), currently being one of the most dynamically developing production methods, is increasingly used in many different areas of industry. Nowadays, apart from the possibility of making prototypes of future products, AM is also used to produce fully functional machine parts, which is known as Rapid Manufacturing and also Rapid Tooling. Rapid Manufacturing refers to the ability of the software automation to rapidly accelerate the manufacturing process, while Rapid Tooling means that a tool is involved in order to accelerate the process. Abrasive processes are widely used in many industries, especially for machining hard and brittle materials such as advanced ceramics. This paper presents a review on advances and trends in contemporary abrasive machining related to the application of innovative 3D printed abrasive tools. Examples of abrasive tools made with the use of currently leading AM methods and their impact on the obtained machining results were indicated. The analyzed research works indicate the great potential and usefulness of the new constructions of the abrasive tools made by incremental technologies. Furthermore, the potential and limitations of currently used 3D printed abrasive tools, as well as the directions of their further development are indicated.

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Stereolithography vs. Direct Light Processing for Rapid Manufacturing of Complete Denture Bases: An In Vitro Accuracy Analysis

Journal of Clinical Medicine ◽

10.3390/jcm10051070 ◽

2021 ◽

Vol 10 (5) ◽

pp. 1070 ◽

Cited By ~ 1

Author(s):

Alexey Unkovskiy ◽

Franziska Schmidt ◽

Florian Beuer ◽

Ping Li ◽

Sebastian Spintzyk ◽

...

Keyword(s):

Root Mean Square ◽

Complete Denture ◽

Rapid Manufacturing ◽

Accuracy Analysis ◽

Mean Square ◽

Heat Map ◽

Denture Base ◽

Multiple Comparison Test ◽

Direct Light

The topical literature lacks any comparison between stereolithography (SLA) and direct light processing (DLP) printing methods with regard to the accuracy of complete denture base fabrication, thereby utilizing materials certified for this purpose. In order to investigate this aspect, 15 denture bases were printed with SLA and DLP methods using three build angles: 0°, 45° and 90°. The dentures were digitalized using a laboratory scanner (D2000, 3Shape) and analyzed in analyzing software (Geomagic Control X, 3D systems). Differences between 3D datasets were measured using the root mean square (RMS) value for trueness and precision and mean and maximum deviations were obtained for each denture base. The data were statistically analyzed using two-way ANOVA and Tukey’s multiple comparison test. A heat map was generated to display the locations of the deviations within the intaglio surface. The overall tendency indicated that SLA denture bases had significantly higher trueness for most build angles compared to DLP (p < 0.001). The 90° build angle may provide the best trueness for both SLA and DLP. With regard to precision, statistically significant differences were found in the build angles only. Higher precision was revealed in the DLP angle of 0° in comparison to the 45° and 90° angles.

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Bioactive multifunctional hopeite coatings on new generation SS254 steel by laser rapid manufacturing for bone implant applications

Transactions of the IMF ◽

10.1080/00202967.2020.1777689 ◽

2020 ◽

Vol 98 (4) ◽

pp. 209-216

Author(s):

Ashish Das ◽

Mukul Shukla

Keyword(s):

Rapid Manufacturing ◽

Bone Implant ◽

Laser Rapid Manufacturing ◽

New Generation

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SHEARING TESTS APPLIED TO PANTOGRAPHIC STRUCTURES

Acta Polytechnica CTU Proceedings ◽

10.14311/app.2017.7.0001 ◽

2016 ◽

Vol 7 ◽

pp. 1 ◽

Cited By ~ 12

Author(s):

Gregor Ganzosch ◽

Francesco Dell’Isola ◽

Emilio Turco ◽

Tomasz Lekszycki ◽

Wolfgang H. Müller

Keyword(s):

Rapid Manufacturing ◽

Pantographic Structures ◽

Deformation Response ◽

Shear Loads ◽

Generalized Continuum ◽

Complete Failure ◽

Elastic Cylinders ◽

Inextensible Fibers ◽

Fabric Materials ◽

Continuum Theories

With the advancements in 3D printing technology, rapid manufacturing of fabric materials with complex geometries became possible. By exploiting this technique, different materials with different structures have been developed in the recent past with the objective of making generalized continuum theories useful for technological applications. So-called pantographic structures are introduced: Inextensible fibers are printed in two arrays orthogonal to each other in parallel planes. These superimposed planes are inter-connected by elastic cylinders. Five differently-sized samples were subjected to shear-like loading while their deformation response was analyzed. Results show that deformation behavior is strong non-linear for all samples. Furthermore, all samples were capable to resist considerable external shear loads without leading to complete failure of the whole structure. This extraordinary behavior makes these structures attractive to serve as an extremely tough metamaterial.

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