Hyper-TVT is a computer-aided education system that has been developed at the Institute of Process Engineering at the ETH Zurich. The aim was to create an interactive learning environment for chemical and process engineering students. The topics covered are the most important multistage separation processes, i.e. fundamentals of separation…

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)

Traces the evolution of instructional computing in the design and control courses. Discusses process design, process control, and expert systems. Concludes that the computing tools for undergraduate instruction are mostly in step with design and control practice in chemical engineering. (CW)

Describes a polymerization reactor engineering course offered at Michigan Technological University which focuses on the design and operation of industrial polymerization reactors to achieve a desired degree of polymerization and molecular weight distribution. Provides a list of the course topics and assigned readings. (TW)

Presents three specific examples of chemical engineering problems which can be interactively solved on personal computers with commercially available software. Illustrates the potential impact of interactive problem solving on chemical engineering. Discusses how this has been accomplished at Ben Gurion University (Israel) and the University of…

Discusses data on chemical research and development (R&D). Areas addressed include sources of R&D funds, R&D spending by the federal government and by industry, and sources of academic R&D funds. provides charts and tables and data on scientists/engineers, budgets, comparisons between applied/basic R&D, abstracts in chemical…

Presents a challenge statement from the Council for Chemical Research (CCR) Education Committee that substantiates the need for changes in the education of chemical engineering graduates. Recommendations are based on answers to survey questions. (DDR)

Provides three classroom examples showing students how chemical engineering techniques can supply partial answers to social questions, such as environmental issues. Examples are depletion of the ozone layer, nuclear winter, and air pollution by chemical solvents. (YP)

Described are the use of spreadsheet programs in chemical engineering calculations using Lotus 1-2-3 macros. Discusses the macro commands, subroutine operations, and solution of partial differential equation. Provides examples of the subroutine programs and spreadsheet solution. (YP)

Points out a different and much simpler approach for the study of equilibria of multiple and heterogeneous chemical reactions. A simulation on coal methanation is used to teach the technique. An example and the methodology used are provided. (MVL)

A course where students were required to choose projects and provide studies of the feasibility, consumer need, and process design is discussed. Other projects such as advertising campaigns used to encourage student creativity are discussed. The need to keep second semester seniors interested is stressed. (MVL)

Considered is the importance of teaching creativity in the field of chemical engineering. Lists major concepts in teaching creativity. Suggests ways of bringing creativity into chemistry instruction. (MVL)

Discussed is the importance of engineering students having effective communication skills so they will be able to discuss their work, present their findings, and propose a course of action. Suggestions for organizing and delivering presentations are included. (KR)

Discussed are the possible uses of spreadsheets in the undergraduate curriculum in chemical engineering classes. The advantages and flexibility of spreadsheets, spreadsheet instruction, graphing capabilities, assignment examples, and conclusions are described. (KR)

Discusses the use of computer-assisted programs that allow chemical engineering students to study textbook thermodynamics problems from different perspectives, including the classical graphical method, while utilizing more than one property correlation and/or operation model so that comparisons can be made and sensitivities determined more…