The aim of this report is to encourage enhanced richness and relevance of the undergraduate engineering education experience, and thus produce better-prepared and more globally competitive graduates, by providing practical guidance for incorporating real world experience in US engineering programs. The report, a collaborative effort of the…

Create a light and sound show to entertain friends. Design an improved safety device for a car. Develop a 2-3 minute voice-over for a sports clip explaining the physics involved in the sport. Modify the design of a roller coaster to meet the needs of a specific group of riders. Design an appliance package for a family limited by the power and…

Since its initial funding by the National Science Foundation in 2004, the National Center for Engineering and Technology Education (NCETE) has worked to understand the infusion of engineering design experiences into the high school setting. Over the years, an increasing number of educators and professional groups have participated in the expanding…

Presented is a two-year associate degree curriculum for Engineering Technology. Specializations are provided in civil, electronics, and mechanical technology. The civil engineering technology specialization facilitates three major areas of study, and mechanical technology includes design and production options. Each curriculum was designed to…

Describes the undergraduate chemical engineering curriculum at the Speed Scientific School of the University of Louisville. The history of the department, a description of the chemical engineering courses, and the strengths and weaknesses of the program are also included. (HM)

Lists articles and books related to engineering technology education published in 1988. Items are grouped administration, aeronautical, architectural, CAD/CAM, civil, computers, curriculum, electrical/electronics, industrial, industry/government/employers, instructional technology, laboratories, lasers, liberal studies, manufacturing, mechanical,…

This paper outlines the work in progress undertaken by the School of Engineering Technology faculty to identify, assess, and develop a course to address the depth and breadth of drafting/plan preparation and plan reading skills required by the various engineering technology programs offered at Youngstown State University. The methodology used to…

Describes a course, including content, reading list, and presentation on chemical reactors at Cambridge University, England. A brief comparison of chemical engineering education between the United States and England is also given. (JN)

Describes an undergraduate chemical engineering course which was designed at North Carolina State University to introduce the experimental side of chemical process technology. The course lectures, experiments, objectives, evaluation and information sources are also discussed. (HM)

Reports on a study designed to determine the current status of courses in engineering materials and their relationship to machine design and design project courses in mechanical engineering technology programs. Includes discussions of two recommendations of the study that were endorsed by a national conference. (TW)

Offers perspectives on the future of chemical engineering. Addresses concerns related to changes in the engineering industry, the role of chemical engineers, and changes in the education of engineers. Includes recommendations for curricular change. (ML)

Describes an undergraduate chemical engineering course which has been taught by a self-paced instructional method at Howard University, Washington, D.C. The instructional method, course description, and students' grades are also discussed. (HM)

Describes an undergraduate chemical engineering course which has been offered at the Georgia Institute of Technology. The objectives, structure, instructional materials and content of this course, which emphasizes the structure and usage of computer-aided design systems, are also included. (HM)

Addresses several concerns regarding the identity of the field of engineering technology. Discusses engineering technology from the standpoint of its designation as a discipline, its body of knowledge, its professional status, its academic faculty, and the structure and policies that will allow it the most options for the future. (TW)

Discusses the needs and properties of human systems including issues of safety and the holistic approach in engineering. Lists a suggested introductory engineering curriculum. Describes characteristics of future realities in managing technology. (YP)