These volumes present the general parctitioners in engineering with a comprehensive discussion of technological surfaces, their interactions with environments, and the various modification techniques available to improve their performance. In each subject, applications to metals, ceramics, and polymers are emphasized. The interactions with the environment are described: corrosion (chemical), friction and waer (mechanical), and bioreactivity (physiological). Reviews of major modification schemes such as chemical vapor deposition, physical vapor deposition, laser beam interactions, chemical infusion, and ion implantation are presented. In summary, reviews of applications of the modification techniques to optimize the performances of structural components, tools, electronic devices, and implantable medical devices, manufactured out of metals, ceramic, and polymers, are described.

Mastering Surface Modeling with SOLIDWORKS 2021 focuses on surfacing tools, an important aspect of SOLIDWORKS’ design capabilities that fills in the gaps that might be left by using solid modeling alone. If you are a SOLIDWORKS user currently relying on solid modeling for designs, or are just not familiar with surface modeling techniques, this book will add these skills to your repertoire to help you create the highest-quality models. For instructors teaching this advanced skillset, this book’s proven techniques, practical examples and training files will give students a broad understanding of the procedures needed to build freeform shapes and place them well on their way to creating sophisticated surface designs of their own. This manual is one of only a few on the market completely dedicated to mastering surfacing tools. Each of the ten chapters has clean, clear instructions with plentiful diagrams to lead you through carefully selected exercises based on the author’s own work experience and techniques. You are guided from a review of surfacing basics, to advanced surface modeling of real-world objects, to an explanation and example of hybrid modeling, to surface repairs and patches. Peruse the table of contents and pick and choose the chapters you are interested in or complete all chapters consecutively to give you an in-depth understanding of all the tools and procedures needed to create surface designs. The projects you will work on in this book include a shoehorn, computer mouse, phone case, a modem housing, and stents. Woven into each of these are procedures, approaches and solutions for possible issues that might arise when you are using surfacing tools. These can be applied to any project you create. Each project touches on a variety of frequently used commands such as extrude, loft, boundary, and sweep; surface revolved, filled, split, and knit; using deform and configurations; mirroring bodies; creating an axis, curve driven and circular patterns, fillets, and molded parts. Look for the post-it notes next to commands for helpful tips and definitions. Throughout the book, you will learn techniques of hybrid modeling, the combination of surface and solid modeling. The last part of the book takes it one step further. Chapter 8 examines hybrid modeling in-depth, guiding you step-by-step from a 2D sketch to the final product, a handle housing. The last two chapters focus on molded parts, creating and saving visual properties of models and how to repair faulty surfaces. The advanced surfacing tools and techniques in this book give you the confidence to tackle projects using hybrid modeling. It is the best method to take full advantage of SOLIDWORKS’ modeling power and create more complex designs.

This book offers a comprehensive introduction to Subdivision Surface Modeling Technology focusing not only on fundamental theories but also on practical applications. It furthers readers’ understanding of the contacts between spline surfaces and subdivision surfaces, enabling them to master the Subdivision Surface Modeling Technology for analyzing subdivision surfaces. Subdivision surface modeling is a popular technology in the field of computer aided design (CAD) and computer graphics (CG) thanks to its ability to model meshes of any topology. The book also discusses some typical Subdivision Surface Modeling Technologies, such as interpolation, fitting, fairing, intersection, as well as trimming and interactive editing. It is a valuable tool, enabling readers to grasp the main technologies of subdivision surface modeling and use them in software development, which in turn leads to a better understanding of CAD/CG software operations.

The book discusses the theoretical fundamentals of CAD graphics to enhance readers’ understanding of surface modeling and free-form design by demonstrating how to use mathematical equations to define curves and surfaces in CAD modelers. Additionally, it explains and describes the main approaches to creating CAD models out of 3D scans of physical objects. All CAD approaches are demonstrated with guided examples and supported with comprehensive engineering explanations. Furthermore, each approach includes exercises for independent consolidation of advanced CAD skills. This book is intended for engineers and designers who are already familiar with the basics of modern CAD tools, e.g. feature based and solid based modeling in 3D space, and would like to improve and expand their knowledge and experience. It is also an easy-to use guide and excellent teaching and research aid for academics and practitioners alike.

1 Aims and Features of This Book The contents of t. his book were originally planned t. o be included in a book en titled Geometric lIIodeling and CAD/CAM to be written by M. Hosaka and F. Kimura, but since the draft. of my part of the book was finished much earlier than Kimura's, we decided to publish this part separately at first. In it, geometrically oriented basic methods and tools used for analysis and synthesis of curves and surfaces used in CAD/CAM, various expressions and manipulations of free-form surface patches and their connection, interference as well as their qualit. y eval uation are treated. They are important elements and procedures of geometric models. And construction and utilization of geometric models which include free-form surfaces are explained in the application examples, in which the meth ods and the techniques described in this book were used. In the succeeding book which Kimura is to write, advanced topics such as data structures of geometric models, non-manifold models, geometric inference as well as tolerance problems and product models, process planning and so on are to be included. Conse quently, the title of this book is changed to Modeling of Curves and Surfaces in CAD/CAM. Features of this book are the following. Though there are excellent text books in the same field such as G. Farin's Curves and Surfaces for CAD /CAM[l] and C. M.

• Teaches SOLIDWORKS users advanced surface modeling skills • Includes tips and techniques for hybrid modeling • Uses clear, step-by-step instructions to help you create real-world projects • Covers how to make molded parts and repair and patch surfaces Mastering Surface Modeling with SOLIDWORKS 2020 focuses on surfacing tools, an important aspect of SOLIDWORKS’ design capabilities that fills in the gaps that might be left by using solid modeling alone. If you are a SOLIDWORKS user currently relying on solid modeling for designs, or are just not familiar with surface modeling techniques, this book will add these skills to your repertoire to help you create the highest-quality models. For instructors teaching this advanced skillset, this book’s proven techniques, practical examples and training files will give students a broad understanding of the procedures needed to build freeform shapes and place them well on their way to creating sophisticated surface designs of their own. This manual is one of only a few on the market completely dedicated to mastering surfacing tools. Each of the ten chapters has clean, clear instructions with plentiful diagrams to lead you through carefully selected exercises based on the author’s own work experience and techniques. You are guided from a review of surfacing basics, to advanced surface modeling of real-world objects, to an explanation and example of hybrid modeling, to surface repairs and patches. Peruse the table of contents and pick and choose the chapters you are interested in or complete all chapters consecutively to give you an in-depth understanding of all the tools and procedures needed to create surface designs. The projects you will work on in this book include a shoehorn, computer mouse, phone case, a modem housing, and stents. Woven into each of these are procedures, approaches and solutions for possible issues that might arise when you are using surfacing tools. These can be applied to any project you create. Each project touches on a variety of frequently used commands such as extrude, loft, boundary, and sweep; surface revolved, filled, split, and knit; using deform and configurations; mirroring bodies; creating an axis, curve driven and circular patterns, fillets, and molded parts. Look for the post-it notes next to commands for helpful tips and definitions. Throughout the book, you will learn techniques of hybrid modeling, the combination of surface and solid modeling. The last part of the book takes it one step further. Chapter 8 examines hybrid modeling in-depth, guiding you step-by-step from a 2D sketch to the final product, a handle housing. The last two chapters focus on molded parts, creating and saving visual properties of models and how to repair faulty surfaces. The advanced surfacing tools and techniques in this book give you the confidence to tackle projects using hybrid modeling. It is the best method to take full advantage of SOLIDWORKS’ modeling power and create more complex designs.

This report describes in detail a new rigorous and systematic verification and validation process for computational models for simulating free surface flows.

Modeling in Geotechnical Engineering is a one stop reference for a range of computational models, the theory explaining how they work, and case studies describing how to apply them. Drawing on the expertise of contributors from a range of disciplines including geomechanics, optimization, and computational engineering, this book provides an interdisciplinary guide to this subject which is suitable for readers from a range of backgrounds. Before tackling the computational approaches, a theoretical understanding of the physical systems is provided that helps readers to fully grasp the significance of the numerical methods. The various models are presented in detail, and advice is provided on how to select the correct model for your application. - Provides detailed descriptions of different computational modelling methods for geotechnical applications, including the finite element method, the finite difference method, and the boundary element method - Gives readers the latest advice on the use of big data analytics and artificial intelligence in geotechnical engineering - Includes case studies to help readers apply the methods described in their own work

A comprehensive introduction to SOLIDWORKS using tutorial style, step-by-step instructions Designed for beginning or intermediate SOLIDWORKS users Learn to create parts and assemblies using machined, plastic and sheet metal components Also covers Simulation, Sustainability, and Intelligent Modeling techniques Includes bonus chapters on the CSWA exam and 3D printing Engineering Design with SOLIDWORKS 2022 is written to assist students, designers, engineers and professionals. The book provides a solid foundation in SOLIDWORKS by utilizing projects with step-by-step instructions for the beginner to intermediate SOLIDWORKS user featuring machined, plastic and sheet metal components. Desired outcomes and usage competencies are listed for each project. The book is divided into five sections with 11 projects. Project 1 - Project 6: Explore the SOLIDWORKS User Interface and CommandManager, Document and System properties, simple and complex parts and assemblies, proper design intent, design tables, configurations, multi-sheet, multi-view drawings, BOMs, and Revision tables using basic and advanced features. Additional techniques include the edit and reuse of features, parts, and assemblies through symmetry, patterns, configurations, SOLIDWORKS 3D ContentCentral and the SOLIDWORKS Toolbox. Project 7: Understand Top-Down assembly modeling and Sheet Metal parts. Develop components In-Context with InPlace Mates, along with the ability to import parts using the Top-Down assembly method. Convert a solid part into a Sheet Metal part and insert and apply various Sheet Metal features. Project 8 - Project 9: Recognize SOLIDWORKS Simulation and Intelligent Modeling techniques. Understand a general overview of SOLIDWORKS Simulation and the type of questions that are on the SOLIDWORKS Simulation Associate - Finite Element Analysis (CSWSA-FEA) exam. Apply design intent and intelligent modeling techniques in a sketch, feature, part, plane, assembly and drawing. Project 10: Comprehend the differences between additive and subtractive manufacturing. Understand 3D printer terminology along with a working knowledge of preparing, saving, and printing CAD models on a low cost printer. Project 11: Review the Certified SOLIDWORKS Associate (CSWA) program. Understand the curriculum and categories of the CSWA exam and the required model knowledge needed to successfully take the exam. The author developed the industry scenarios by combining his own industry experience with the knowledge of engineers, department managers, vendors and manufacturers. These professionals are directly involved with SOLIDWORKS every day. Their responsibilities go far beyond the creation of just a 3D model.

Water Engineering Modeling and Mathematic Tools provides an informative resource for practitioners who want to learn more about different techniques and models in water engineering and their practical applications and case studies. The book provides modelling theories in an easy-to-read format verified with on-site models for specific regions and scenarios. Users will find this to be a significant contribution to the development of mathematical tools, experimental techniques, and data-driven models that support modern-day water engineering applications. Civil engineers, industrialists, and water management experts should be familiar with advanced techniques that can be used to improve existing systems in water engineering. This book provides key ideas on recently developed machine learning methods and AI modelling. It will serve as a common platform for practitioners who need to become familiar with the latest developments of computational techniques in water engineering. - Includes firsthand experience about artificial intelligence models, utilizing case studies - Describes biological, physical and chemical techniques for the treatment of surface water, groundwater, sea water and rain/snow - Presents the application of new instruments in water engineering