Diploma Manufacturing Technology Book Pdf
Flaviano Goldammer
This course presents material in both class and laboratory format. Topics covered include: dimensioning, print reading, auxiliary views, graphs, screw threads, gears, and the design process. Working in teams, a major design project with written and oral reports is required.
This course introduces the student to the use of CAD for construction of basic shapes and multi view drawings. It is a project oriented course introducing the student to graphic design using AutoCAD. AutoCAD, as it is applied in MTEC.2000, is a two dimensional CAD program used to produce computer design models. Course stresses hands-on work with AutoCAD. Course is a fundamentals approach and requires no experience with other CAD programs.
Students will develop an understanding of precision metrology and the machine tools, related equipment, and systems used in manufacturing. Students will learn the inter-relationships between machine tools, various machining methods, engineering design considerations, and manufacturing techniques studied in the MET program. Lecture, case studies, and laboratory work are supported by a comprehensive text with supplemental materials provided by the instructor to enhance student learning. Students will work with lathes, drill presses, vertical milling machines, and abrasive finishing methods during laboratory sessions to manufacture several precision finished parts from engineering drawings. Course grades will be determined from student performance on examinations and laboratory projects.
This course is an introduction to computer aided manufacturing with an overall perspective focusing on the design process and how computer technology have affected the modern manufacturing environment. Introduces students to computer aided design systems, process engineering, basic tooling design, machining, programmable logic controllers (PLC), fundamentals of numerical control (NC), process planning, and concurrent engineering with the objective of design optimization for manufacturing and commercialization.
The course will focus upon a variety of manufacturing processes used for metals, ceramics and plastics, material interactions that occur during manufacturing, mechanical test methodology and material response to stress at different temperatures, methods to select appropriate processes to achieve product specification and methods to investigate process history based on material properties.
The course will focus upon three primary categories of manufacturing improvement: theory of constraints/workflow, work definition and design, and quality improvement. Each students should understand and be conversant in the principles of productivity and able to lead a productivity improvement project upon successful completion of the course. Case studies will be used to illustrate the proper implementation of productivity improvement principles.
This course introduces students to accounting and finance operations and principles, and how they impact engineering and manufacturing activities in both analytical and forward looking planning activities. Topics covered include financial statements, costing, depreciation, time value of money, cash flows, capital budgeting, and capital recovery with the objective of building working financial models for a technical environment. Pre-Requisites: 49.201 Economics I or instructor permission. Proficiency in MS Excel or equivalent.
Students enrolled in UMass Lowell certificate programs must complete all courses and maintain a grade point average of 2.000 or better to earn the certificate. All certificate courses must be completed within a five-year period.
Tuition at UMass Lowell is typically half the cost of private colleges, and our online tuition is among the lowest in the nation. Tuition for online programs offered through the Division of Graduate, Online & Professional Studies is the same whether you live in-state, out-of-state or outside of the U.S.
Apply to an undergraduate certificate program using the Online Application Form or by printing and completingthe Undergraduate Certificate Application Form in .pdf file format. Applicants will be required to have either their official high school transcript, HiSET, GED or their most recent college transcript if applicable, sent to Graduate, Online & Professional Studies at the address below. Applications, transcripts, and other correspondence should be sent to:
The Bachelor of Science degree in Manufacturing Engineering (MFE) at Eastern Kentucky University is designed to prepare graduates to become practicing manufacturing engineers. The program provides students with the skills to design, analyze, and modify the processes and systems used to make products in the most time-efficient, cost-effective way possible while maintaining safety and product quality in environmentally friendly ways.
Students will gain expertise and practical knowledge in the major areas of manufacturing materials and processes; design for manufacturability; lean manufacturing; quality and process control; safety; automation; and robotics. Graduates will be able to employ a strong base of fundamental engineering and management skills to effectively integrate people, technology, machines, and capital to create positive change as they are involved in the manufacturing process from design to production to finished product.
Manufacturing engineering focuses on the design, development, and optimization of production systems and manufacturing processes. It involves the application of principles of engineering and the use of technology such as advanced materials, robotics, automation, and computer-controlled systems to improve manufacturing processes.
Manufacturing engineering plays a crucial role in the production of goods and products that are used by people around the world. The B.S. in Manufacturing Engineering degree leads to a career with great return on investment, career satisfaction, and graduates are in demand.
Graduates of the Manufacturing Engineering program are prepared for professional careers in numerous local, regional, and world industries. These include automotive, aerospace, medical, and technology. Engineering graduates are valued in many other areas as well, due to the emphasis on math, science, and problem solving.
Employment demand for manufacturing engineers has been very strong. In a recent three-year period, there were 423 posted job openings for manufacturing engineers in Kentucky and 8,618 job postings nationally. Moreover, EKU is the only destination in the Commonwealth to offer this unique program.
Manufacturing job growth, both in Kentucky and nationally, will be significant in the next 10 years, with an annual growth of 4.12% in the number of jobs, and an anticipated increase of 32,400 new jobs nationally by 2029. Manufacturing sectors in Kentucky, like motor vehicle seating manufacturing, are projected to grow by 38%, and aerospace manufacturing anticipates a 21% increase over the coming decade.
The department is located in the Ralph W. Whalin Technology Complex, which includes approximately 100,000 square feet of classroom and laboratory space. Laboratories housed in the Whalin Complex include aviation, automation, electronics, computer aided drafting (CAD), 3D printing, quality assurance and metrology, materials and metallic processes, construction estimating, fluid power and computer applications.
The facilities are located in a central area of campus and close to the library, classroom buildings and residence halls. Faculty in the department have diversified backgrounds in academics and professional experience. They are knowledgeable, enthusiastic and devoted to providing students with the skills necessary to succeed.
Q: What is manufacturing engineering?
A: Manufacturing engineering is a branch of engineering focused on the design, development and operation of integrated systems for the production of high-quality products used in everyday life. Manufacturing engineers must advise on the best technologies and processes to manufacture a particular product and design the environment where it will be produced. While other engineering disciplines (e.g., electrical, chemical, mechanical) are involved in aspects of manufacturing, manufacturing engineering is the discipline that designs and operates the overall systems of manufacturing.
Q: What is a manufacturing engineer?
A: The short answer is manufacturing engineers are professional problem-solvers. They use math and science, along with skills in critical thinking, to find practical solutions to design and/or improve products and processes.
Manufacturing engineers DO things: they design, develop, prototype, fabricate, improve, invent and make everyday products. These products range from daily items used in the home or office from autos and trucks to aerospace products and aircraft. Kentucky has an extensive network of manufacturing companies, with manufacturing companies in virtually every county, all needing manufacturing engineers. Automotive and aerospace are the top two exports.
Q: As a manufacturing engineer, what skills will I need?
Manufacturing engineers are very versatile and require a diverse skill set that includes analytical, technical, communication and organizational skills. This combination of skills will help prepare you to lead employees, improve operational efficiency and solve problems on the spot.
Q: What do I need to take in high school to prepare to be an engineer?
A: Engineering is a challenging field that requires an aptitude for mathematics and science. In high school, you should take as many upper-level math and science courses as possible. These courses include math through algebra I and II, geometry and trigonometry, physics and chemistry. In addition, practical, hands-on courses in pre-engineering and at least one year of hands-on computer experience is strongly recommended.
Q: How will credits transfer?
A: Eastern Kentucky University works closely with transfer students to ensure courses that are not already in the transfer portal are evaluated quickly and applied where appropriate.