Alex C. Roschli; Michael C. Borish; Abby K. Barnes; Thomas A. Feldhausen; Peter Wang; Eric MacDonald Elsevier (2023) Saatavuus: Tilaustuote Pehmeäkantinen kirja
Thomas M. Haladyna; Tushar K. Ghosh; Mark A. Prelas; Dabir S. Viswanath; Sudarshan K. Loyalka Taylor & Francis Inc (2009) Saatavuus: Tilaustuote Kovakantinen kirja
Mark A. Richardson; Paul W. Flint; Bruce H. Haughey; Valerie J. Lund; John K. Niparko; K. Thomas Robbins; J. Regan Thomas Mosby (2010) Saatavuus: Loppuunmyyty Kovakantinen kirja
Thomas Kovach; Andreas Thomasberger; Benjamin K. Bennett; Douglas A. Joyce; Ellen Ritter Camden House (2010) Saatavuus: Painos loppu Pehmeäkantinen kirja
Roger K. Freeman; Thomas J. Garite; Michael P. Nageotte; Lisa A Miller Lippincott Williams and Wilkins (2012) Saatavuus: Tilaustuote Kovakantinen kirja
Sabu Thomas; Chin Han Chan; Laly A. Pothen; Rajisha K. R.; Jithin Joy; Hanna J. Maria Royal Society of Chemistry (2013) Saatavuus: Tilaustuote Moniviestin
A. K. Haghi; Eduardo A. Castro; Sabu Thomas; P. M. Sivakumar; Andrew G. Mercader Apple Academic Press Inc. (2015) Saatavuus: Tilaustuote Kovakantinen kirja
Motion and Path Planning for Additive Manufacturing takes a deep dive into the concepts and computations behind slicing software - the software that uses 3D models to generate the commands required to control the motion of a 3D printer and ultimately construct objects.
Starting with a brief review of the different types of motion in additive systems, this book walks through the steps of the path planning process and discusses the different types of toolpaths and their corresponding function in additive manufacturing. Planar, non-planar, and off-axis path planning are examined and explained. This book also presents pathing considerations for different types of 3D-printers, including extrusion, non-extrusion, and hybrid systems as well as 3- and 5-axis systems.
Engineers, researchers, and designers in the additive manufacturing field can use this book as a reference for every step of the path planning process, as well as a guide that explains the computations underlying the creation and use of toolpaths.
Outlines the entire toolpath planning process required to go from a computer-aided design (CAD) model to G-code that a 3D printer can then use to construct a part
Defines the terms and variables used in slicing and other path-planning software
Highlights all the available kinematic arrangements for motion systems in additive manufacturing as well as the advantages and risks of each method
Discusses the nuances of path planning for extrusion, non-extrusion, and hybrid process as well as 3- and 5-axis additive systems
Provides an up-to-date explanation of advancements in toolpath planning and state-of-the-art slicing processes that use real-time data collection