I am delighted to announce that I am serving as the Guest Editor for a Special Issue on "Design Process for Additive Manufacturing" in Designs, under the section "Smart Manufacturing System Design".
Dear Colleagues,
Additive manufacturing (AM) processes are rapidly growing technologies that can produce highly complex models. Depending on the manufacturing method, the size of the part, and its complexity, it can take several hours or even days to create finished models using additive techniques. There is currently a wide variety of additive manufacturing methods available. AM models are widely utilized in the automotive, aerospace, and medical industries. Since functional models are often produced using additive technologies, they must meet the requirements related to, for example, strength assessments, dimensional-geometric tolerancing, and surface roughness.
A person designing a 3D-CAD model for 3D printing must prepare it so that its geometric parameters meet the most favorable operating conditions related to tightness, accuracy, connection between components, wear, or deformation, among other things. This task is challenging as each 3D printing technology has its technical limitations, which cause the produced model to often differ significantly from the designer's assumptions. Therefore, it is necessary to develop procedures at the design and manufacturing stages to minimize these differences.
When creating a 3D-CAD model for 3D printing, traditional modeling using Computer-Aided Design (CAD) systems is commonly used. Challenges arise when technological or material documentation is not available for a product. This is especially common when designing models of anatomical structures, museum artifacts, or other complex geometric models where solid or surface design is usually impossible. The reverse engineering (RE) process can solve this problem thanks to the advancements in coordinate measuring systems, data processing software, and modern manufacturing techniques. This design process is also frequently used for developing 3D-CAD models for 3D printing, but it can lead to geometric mapping errors during the design stage. Therefore, it is necessary to develop procedures at the geometry design stage of the RE process to minimize these errors.
Given the current state of the literature, standards related to the traditional design of 3D-CAD models and the RE process for AM still need to be developed. The lack of a development of assumptions using the AM technique in the design and manufacturing stage greatly restricts the commercialization of finished products for the automotive, aerospace, and/or medical industries. Therefore, it is necessary to pay attention to this research problem.
Dr. Paweł Turek Guest Editor
Paweł Turek Pawel, I'm sorry. I don't agree with your premise; "The lack of a development of assumptions using the AM technique in the design and manufacturing stage greatly restricts the commercialization..etc etc.
The sensibility of design and development of "additive manufacturing" is not a new and/or under addressed problem. Nor is additive 3-D manufacturing. In my opinion the phrase, additive manufacturing" is the only new thing. The rest, the variety of processes and technology are eons old. For example, the first tools, weaving cloth, making shelters and on and on are "additive".
You might consider the history of technology, the arts, medicine, science is additive. Even life itself is an additive process.
Hi Pawel, how is the process to publish a paper in the journal? Where do I send a contribution for review?
best regards
Joachim
Thank you for the information Lee Clawson. Of course, designing and manufacturing objects for additive manufacturing is already well known. I focus on finding new solutions/procedures to streamline the modeling process and manufacturing models using 3D printing methods for the open special issue. Particularly important is to develop at the stage of CAD modeling or in the RE process such digital models so that they meet design assumptions after 3D printing techniques, e.g., assemblability (e.g., screw and nut connections), and in the case of the manufacturing stage to focus on establishing technological parameters that, e.g., guarantee the appropriate quality of the surface texture, which, e.g., allows better ingrowth of the implant into the patient's bone structure
Thank you for the information and interest in the special number Joachim Günther . If you would like to submit an article for review, please go to the link.
https://www.mdpi.com/journal/designs/special_issues/8A27O796W2#info
On the left, you will find a 'Submit to Special Issue' tab. Here, you can upload your file, among other necessary steps. Please note that this special issue is part of the 'Smart Manufacturing System Design' section.
If you have any problems, you can contact me at [email protected] or, better, [email protected], the person responsible from the technical side for running this special issue.
Kind regards,
Paweł
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