Indicates that changes in the industrial economy have reflected educational needs for engineering students. Cites technical content, communication and interpersonal skills and industry functions as improvement areas. Describes curriculum changes, course specifics, technology, and management tools. (RT)

Describes a workshop conducted at the University of Pittsburgh for chemical engineering students regarding graduate education opportunities. Reviews the purposes of the workshop, benefits of getting a graduate degree, and provides a sample of the questions discussed by the invited panelists. (TW)

Describes a laboratory experiment for freeze-drying fruits and vegetables which aims to expose college students to the principles of drying and simultaneous heat and mass transfer. The experimental apparatus, procedure of the experiment, and data analysis are also included. (HM)

Differentiates among science, engineering, design, and technology. Examines recent recommendations that accreditation criteria for engineering science and engineering design be changed. Provides five guidelines for the development of design experiences which would permeate the entire chemical engineering curriculum. (TW)

Uses heat exchange, evaporator, and distillation pressure examples to illustrate ways of motivating students to participate creatively and generate questions on process engineering logic. Relates the need for providing a link between theory and industrial practice. (RT)

Presents some of the work currently under way in the development of microgravity chemical processes. Highlights some of the opportunities for materials processing in outer space. Emphasizes some of the contributions that chemical engineers can make in this emerging set of technologies. (TW)

Describes some of the features of Lehigh University's (Pennsylvania) process modeling and control program. Highlights the creation and operation of the Chemical Process Modeling and Control Center (PMC). Outlines the program's philosophy, faculty, technical program, current research projects, and facilities. (TW)

Describes a course for third- or fourth-year chemical engineering students designed to acquaint them with the chemical industry. The course deals with productivity, characteristics of the chemical industry, sources of information, industrial intelligence, research and development, patent law, technology transfer, and quality control. (TW)

A class in which students learn about the roles that chemical engineers play in a variety of industries is described. Outlines from the first two class offerings and discussions of the use of guest speakers, videos, plant visits, student projects, and grading are included. (KR)