Additive Manufacturing

Director and Professor of Practice

Craig A. Brice

Master of Science in Additive Manufacturing (Non-Thesis) (30 credits)

The Master of Science in Additive Manufacturing (Non-Thesis) provides students the opportunity to explore a wide range of manufacturing technologies and methodologies necessary to fabricate engineered products in current and emerging markets.

The core courses in the Additive Manufacturing program give students a foundation in additive manufacturing along with options to explore topics across various fabrication and manufacturing efficiency areas. Students enrolled in the Master of Science in Additive Manufacturing (Non-Thesis) program will complete 9 credits of core courses listed below along with 21 credits of elective courses from the Additive Manufacturing list. The elective list is broken into focus areas to aid students interested in a specific area of additive manufacturing. Students are not required to select a focus area but can choose electives across the entire list. To achieve the Master of Science (Non-Thesis), only 9 of the 30 required credits can be coursework at the 400-level or lower.

AMFG401ADDITIVE MANUFACTURING3.0
or AMFG501 ADDITIVE MANUFACTURING
AMFG421DESIGN FOR ADDITIVE MANUFACTURING3.0
or AMFG521 DESIGN FOR ADDITIVE MANUFACTURING
AMFG531MATERIALS FOR ADDITIVE MANUFACTURING3.0
ELECTIVES Select electives from the Additive Manufacturing list below Up to 6 hours may be replaced with project-based independent study21.0
Total Semester Hrs30.0

Mines' Combined Undergraduate / Graduate Degree Program

Students enrolled in Mines’ combined undergraduate/graduate program may double count up to six credits of graduate coursework to fulfill requirements of both their undergraduate and graduate degree programs. These courses must have been passed with “B-” or better, not be substitutes for required coursework, and meet all other University, Department, and Program requirements for graduate credit.

Students are advised to consult with their undergraduate and graduate advisors for appropriate courses to double count upon admission to the combined program.

Additive Manufacturing Electives

Note that, while the listed electives are grouped into focus areas, students are not required to select a specific focus area for their degree. 

Materials Manufacturing Focus Area
MEGN511FATIGUE AND FRACTURE3.0
MEGN515COMPUTATIONAL MECHANICS3.0
MTGN414ADVANCED PROCESSING AND SINTERING OF CERAMICS3.0
MTGN442ENGINEERING ALLOYS3.0
MTGN445MECHANICAL PROPERTIES OF MATERIALS3.0
MTGN464FORGING AND FORMING2.0
MTGN531THERMODYNAMICS OF METALLURGICAL AND MATERIALS PROCESSING3.0
MTGN536OPTIMIZATION AND CONTROL OF METALLURGICAL SYSTEMS3.0
MTGN557SOLIDIFICATION3.0
MTGN560ANALYSIS OF METALLURGICAL FAILURES3.0
MTGN564ADVANCED FORGING AND FORMING3.0
MTGN565MECHANICAL PROPERTIES OF CERAMICS AND COMPOSITES3.0
ELECT Electives As Approved By Advisor
Design Manufacturing Focus Area
AMFG592ADDITIVE MANUFACTURING BUILD PREPARATION1.0
FEGN525ADVANCED FEA THEORY & PRACTICE3.0
FEGN526STATIC AND DYNAMIC APPLICATIONS IN FEA3.0
FEGN527NONLINEAR APPLICATIONS IN FEA3.0
FEGN528FEA FOR ADVANCED DESIGN APPLICATIONS3.0
MEGN453AEROSPACE STRUCTURES3.0
MEGN481MACHINE DESIGN3.0
ELECT Electives As Approved By Advisor
Manufacturing Controls and Data Science Focus Area
AMFG511DATA DRIVEN ADVANCED MANUFACTURING3.0
CSCI507INTRODUCTION TO COMPUTER VISION3.0
CSCI534ROBOT PLANNING AND MANIPULATION3.0
CSCI562APPLIED ALGORITHMS AND DATA STRUCTURES3.0
CSCI575ADVANCED MACHINE LEARNING3.0
CSCI587CYBER PHYSICAL SYSTEMS SECURITY3.0
DSCI/MATH530STATISTICAL METHODS I3.0
EENG509SPARSE SIGNAL PROCESSING3.0
EENG515MATHEMATICAL METHODS FOR SIGNALS AND SYSTEMS3.0
EENG517THEORY AND DESIGN OF ADVANCED CONTROL SYSTEMS3.0
MATH551COMPUTATIONAL LINEAR ALGEBRA3.0
MEGN441INTRODUCTION TO ROBOTICS3.0
MEGN540MECHATRONICS3.0
MEGN544ROBOT MECHANICS: KINEMATICS, DYNAMICS, AND CONTROL3.0
MEGN545ADVANCED ROBOT CONTROL3.0
MEGN587NONLINEAR OPTIMIZATION3.0
MEGN588INTEGER OPTIMIZATION3.0
ELECT Electives As Approved By Advisor
Manufacturing Optimization and Business Focus Area
AMFG422/522LEAN MANUFACTURING3.0
AMFG423/523DESIGN AND ANALYSIS OF EXPERIMENTS 3.0
MEGN479/579OPTIMIZATION MODELS IN MANUFACTURING3.0
CEEN401/501LIFE CYCLE ASSESSMENT3.0
EBGN559SUPPLY CHAIN ANALYTICS3.0
EBGN563MANAGEMENT OF TECHNOLOGY AND INNOVATION3.0
EBGN576MANAGING AND MARKETING NEW PRODUCT DEVELOPMENTS3.0
MEGN592RISK AND RELIABILITY ENGINEERING ANALYSIS AND DESIGN3.0

Graduate Certificate in Additive Manufacturing (12 credits)

The Graduate Certificate in Additive Manufacturing provides students the knowledge and skills needed to design, fabricate, and implement engineered components made using additive manufacturing techniques.

The Graduate Certificate in Additive Manufacturing is offered fully online to accommodate working professionals outside the immediate geographic area. These courses are also available as elective courses in the current Advanced Manufacturing Masters (Non-Thesis) and Graduate Certificate in Smart Manufacturing.

The core courses in the Additive Manufacturing program explore the process, design, and material aspects of additive manufacturing. Students enrolled in the Graduate Certificate program will complete the three core courses found below along with an elective course from the Additive Manufacturing list. To achieve the Graduate Certificate, only 3 of the 12 required credits can be coursework at the 400-level or lower.

AMFG401ADDITIVE MANUFACTURING3.0
or AMFG501 ADDITIVE MANUFACTURING
AMFG521DESIGN FOR ADDITIVE MANUFACTURING3.0
AMFG531MATERIALS FOR ADDITIVE MANUFACTURING3.0
ELECTIVESelect elective from the Additive Manufacturing list above3.0

Courses

AMFG501. ADDITIVE MANUFACTURING. 3.0 Semester Hrs.

This course gives students a broad understanding of additive manufacturing (AM) techniques (popularly known as 3d printing) and how these techniques are applied to make engineered products. The course covers the seven standard classifications of AM processes and compares and contrasts each technique alongside legacy fabrication methods such as milling. Students will also get a high-level view of design, material, and pre/post-processing requirements for AM produced parts along with a fundamental understanding of the cost drivers that make AM competitive over legacy fabrication methods. Prerequisites: MEGN200 and MEGN201 or equivalent project classes.

AMFG511. DATA DRIVEN ADVANCED MANUFACTURING. 3.0 Semester Hrs.

(I) Although focused on materials manufacturing, this course is intended for all students interested in experimental design and data informatics. It will include both directed assignments to reinforce the concepts and algorithms discussed in class and a term project that will encourage students to apply these concepts to a problem of their choosing. Some programming background would be beneficial but is not necessary; the basics of python and the sklearn machine learning toolkit will be covered in the first weeks of the course. 3 hours lecture; 3 semester hours.

AMFG521. DESIGN FOR ADDITIVE MANUFACTURING. 3.0 Semester Hrs.

(II) Design for Additive Manufacturing (DAM) introduces common considerations that must be addressed to successfully design or re-design parts for additive manufacturing methods. Industry-leading hardware and FEA software will be used to explore all phases of the DAM workflow, including topology optimization, additive process simulation, distortion compensation, and in-service performance. 3 hours lecture; 3 semester hours.

AMFG522. LEAN MANUFACTURING. 3.0 Semester Hrs.

Throughout the course, students will learn to apply skillsets to real world problems, focusing on lean and six-sigma principles and methodologies. The course is taught with a focus on the DMAIC structure of implementation (define, measure, analyze, improve and control) for improving and implementing process efficiencies in industry. The course is split into three general subject areas; 1) lean manufacturing principles, 2) six-sigma and statistical process control (SPC) methodologies and 3) implementation techniques focusing on graphical and numerical representation of processes using R. Students will receive an in-depth overview of lean manufacturing principles and will perform case studies at local industries to implement learned skill-sets. Next, students will step-through several hands-on activities using real products to investigate six-sigma and perform SPC analysis, identifying shifts in process data and learning how to shift processes into capable processes. Lastly, students will learn about various implementation techniques for industry and will perform an in-depth analysis of the course topics based on the industry tours performed.

AMFG523. DESIGN AND ANALYSIS OF EXPERIMENTS. 3.0 Semester Hrs.

This course introduces effective experimental design and analysis methodologies relevant to all engineering and scientific disciplines to maximize the information learned from every experiment (test case) while minimizing the total number of tests. We will be using state-of-art methods steeped in statistics to effectively set up your experiments, understand what the results are telling you, and clearly communicate the results to peers and leadership. We apply a disciplined systems engineering approach across the four major experimental phases: plan, design, execute, and analyze. This hands-on class will focus on understanding concepts and practical applications while relying less on the statistical theoretical development. Completion of MATH201 is recommended, not required.

AMFG531. MATERIALS FOR ADDITIVE MANUFACTURING. 3.0 Semester Hrs.

(II) This course will cover various structural materials used in additive manufacturing (AM) processes. Focus will be on polymer, ceramic, and metallic compositions. General chemistry of each material will be covered with additional focus on the behavior of these materials when processed using AM. The course will span the entire AM lifecycle from feedstock fabrication to fabrication by AM to post processing and inspection of as-fabricated material. Students will have hands-on exposure to AM processes and will conduct laboratory studies of AM material properties. Additionally, students will conduct a semester-long research project exploring some aspect of AM materials. 3 hours lecture; 3 semester hours.

AMFG581. OPTIMIZATION MODELS IN MANUFACTURING. 3.0 Semester Hrs.

This course explores the process of taking known inputs such as costs, supplies and demands, and determining values for unknown quantities (variables) so as to maximize or minimize some goal (objective function) while satisfying a variety of restrictions (constraints). Such problems arise in manufacturing operations as personnel planning, product sequencing, and plant scheduling. We examine a variety of manufacturing settings, e.g., flow shops, job shops, flexible manufacturing shops, and the corresponding appropriate models to optimize operations. The course explores a mix of mathematical modeling, software use and case studies. Prerequisite: Junior standing in an engineering major, or instructor consent.

AMFG591. ECONOMIC CONSIDERATIONS FOR ADDITIVE MANUFACTURING. 1.0 Semester Hr.

This course will provide students an opportunity to explore the economic considerations for advanced manufacturing processes, specifically additive manufacturing (AM). So often, these processes are thought of as being quick, easy, and cheap. While this can be true for prototypes and other non-critical parts, the reality is much different when working with engineered parts. An examination of the underlying engineering details for AM processes reveals many elements of cost and time which must be accounted for when evaluating the affordability of AM for any application. Students will learn about recurring and non-recurring costs, the reasons for post-processing steps such as machining, mechanical testing, and non-destructive inspection, and the impacts of these considerations on cost and manufacturing span-time. Students should expect to come away from this course better equipped to assess the economic viability of AM for engineering applications.

AMFG592. ADDITIVE MANUFACTURING BUILD PREPARATION. 1.0 Semester Hr.

This course covers practical aspects of additive manufacturing build preparation, which include designing a part, part build orientation, and support structures. It distinguishes these concepts from those of traditional manufacturing methods and addresses how they influence final part outcome in regard to mechanical performance, dimensional accuracy, surface finish, and post processing requirements. Similarities and differences in these concepts are covered as they apply to various additive manufacturing technologies. These concepts are integrated to ultimately provide students with the ability to holistically approach design for additive manufacturing. Prerequisite: AMFG401 or AMFG501.

AMFG598. SPECIAL TOPICS IN ADVANCED MANUFACTURING. 1-6 Semester Hr.

(I, II) Pilot course or special topics course. Topics chosen from special interests of instructor(s) and student(s). Usually the course is offered only once. Prerequisite: none. Variable credit; 1 to 6 credit hours. Repeatable for credit under different titles.