Chemical Engineering
www.che.vt.edu/
Erdogan Kiran, Head
Harry C. Wyatt Professor: D.G. Baird
Frank C. Vilbrandt Professor: Y.A. Liu
Fred W. Bull Professor: S.T. Oyama
Professors: E. Kiran
Associate Professors: D.F. Cox; R.M. Davis; K. Forsten Williams; E. Marand
Assistant Professors: A.S. Goldstein
Adjunct Professors: P.L. Durrill
ChE Co-op Advisors: A.S. Goldstein
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Overview
- Skillful and creative applications of the principles of chemistry, biochemistry, biology, mathematics, and physics are needed to solve the problems now confronting society. Whether these problems involve energy, food, health, environmental quality, materials, or whatever impacts us, the modern chemical engineer is the professional concerned with finding economically and socially acceptable solutions. The program prepares graduates for employment in a great variety of industries including the chemical, petroleum, biochemicals, pharmaceutical, paper, environmental, fibers, plastics, food, electronics, and consumer product industries. Students may customize their academic program around an industry of their interest by judiciously selecting electives. For example, areas of concentration such as polymers, biotechnology, marketing, and environmental chemical engineering are common choices.
- The goal of the undergraduate program is to produce chemical engineering graduates who are prepared for professional careers and/or graduate school. In fulfilling this goal the department has set three primary objectives for the graduates:
- Graduates should possess a strong background in the chemical engineering fundamentals;
- Graduates should be able to apply these fundamentals to diverse and meaningful problems;
- Graduates should be able to effectively function in a professional environment.
- The curriculum has been developed to meet the department goal and the objectives for the graduates. The curriculum is demanding and a GPA of at least 2.50 is recommended for transfer into the program at the sophomore level. An average GPA of at least 2.00 in all ChE courses attempted is required for continued enrollment in the department. The department has specific grade policies for continuation in the program and for graduation. For further information on these policies, please contact the department.
- The chemical engineering curriculum integrates studies in thermodynamics, fluid mechanics, heat transfer, mass transfer, process control, reaction kinetics, plant and process design, verbal and written communications, and reaction kinetics, along with professional ethics and environmental awareness. Students gain hands-on experience with the equipment described in the courses during the summer Unit Operations Laboratory. The laboratory and the senior design courses are recognized as two of the high points in the undergraduate program. Throughout these studies, the student learns the elements of the design of chemical processes and chemical processing equipment. The experience culminates in participation in a national senior-level design contest. The computer is a necessary tool in all the courses and the same software used in industry is used in the design courses.
- In addition to the basic undergraduate program outlined here, more sophisticated and specialized programs leading to the M.S. and Ph.D. in chemical engineering also are offered (see Graduate Catalog).
- The department participates in the Cooperative Education Program whereby qualified students may alternate periods of study with periods of professional employment.
- The ChE website may be viewed at: www.che.vt.edu
Chemical Engineering Program
- A total of 135 semester credits are required for graduation (effective with Class of 2006).
- Students planning to enter Chemical Engineering take Analytical Chemistry 2114-2124 as shown in the schedule of classes in the Engineering Education section.
Second Year |
First Semester |
CHE 2114: Mass and Energy Balances |
3 |
3 |
CHEM 2535: Organic Chemistry (or 2565) |
3 |
3 |
CHEM 2545: Organic Chemistry Lab |
3 |
1 |
CHEM 3615: Physical Chemistry |
3 |
3 |
MATH 2224: Calculus |
3 |
3 |
PHYS 2306: Foundations of Physics II |
4 |
4 |
Credits |
|
17 |
Second Semester |
CHE 2124: CHE Simulations |
2 |
2 |
CHE 2164: CHE Thermodynamics |
3 |
3 |
CHEM 2536: Organic Chemistry (or 2566) |
3 |
3 |
CHEM 2546: Organic Chemistry Lab |
3 |
1 |
CHEM 3625: Physical Chemistry Lab |
1 |
1 |
EF 2324: Engr. Problem Solving using Fortran |
1 |
1 |
MATH 2214: Intro to Diff. Equations |
3 |
3 |
Elective |
3 |
3 |
Credits |
|
17 |
Third Year |
First Semester |
CHE 3114: Fluid Transport |
3 |
3 |
CHE 3134: Separation Processes |
3 |
3 |
ENG 3764: Technical Writing |
3 |
3 |
STAT 4604: Statistical Methods for Engineers |
3 |
3 |
MATH 4564: Oper. Methods |
3 |
3 |
Credits |
|
15 |
Second Semester |
ChE 3015: Process Meas. and Controls |
3 |
3 |
CHE 3044: Heat Transfer |
2 |
2 |
CHE 3144: Mass Transfer |
3 |
3 |
CHE 3184: Chemical Reactor Analysis and Design |
3 |
3 |
CHE 4134: Chemical Process Modeling |
2 |
2 |
Elective* |
3 |
3 |
Credits |
|
16 |
Summer Term (must precede senior year) |
ChE 4014: ChE Laboratory |
|
5 |
Fourth Year |
First Semester |
CHE 4104: Process Materials |
3 |
3 |
ChE 4185: Process and Plant Design (WI) |
4 |
4 |
ESM 2214: Statics and Mechanics of Materials |
3 |
3 |
Electives* |
6 |
6 |
Credits |
|
16 |
Second Semester |
ChE 4186: Process and Plant Design (WII) |
4 |
4 |
Electives* |
10 |
10 |
Credits |
|
14 |
* Elective Hours: 25, as specified below
16 hours Core Curriculum (choose from approved lists) -- Areas 2, 3, 6, 7
3 hours Technical Electives (choose from approved list)
6 hours Free Electives
The following are areas of concentration where students could use electives. Lists of approved courses for these concentrations are available in the Department of Chemical Engineering.
- No concentration
- Marketing and Chemical Distribution
- Biochemical Engineering
- Polymers
- Environmental
As part of progress toward a degree, a student must have a grade of C or better in all ChE-prefix courses and maintain a GPA of 2.0 or above in all ChE prefix courses. If in-major GPA drops below 2.0 at any time, the student will be place on departmental probation. The student cannot remain on departmental probation for more than two consecutive semesters. In the case that a student has not achieved an in-major 2.0 or better after two semesters, the student is prohibited from registering for any ChE courses for at least one semester and, after that, only with permission of ChE department head. All ChE credits are used to calculate in-major GPA.
Students who plan to co-op should talk with Dr. Cox (139 Randolph) or Dr. Goldstein (127 Randolph) in the ChE department.
- For additional information about the Chemical Engineering curriculum, please contact the department head.
Undergraduate Course Descriptions (CHE)2114: MASS AND ENERGY BALANCES Stoichiometric and composition relationships, behavior of gases, vapor pressures, solubility, mass balances, recycling operations, energy balances, first law of thermodynamics, thermophysics, thermochemistry, fuels and combustion, application to chemical operations. Pre: CHEM 1074 or 1035; ENGE 1016; MATH 1206. (3H,3C)
2124: CHE SIMULATIONS Many chemical engineering processes lead to sets of linear and nonlinear algebraic equations. This course will focus on numerical methods for solving these types of problems. In addition, techniques for analyzing data to evaluate different models and to obtain model parameters will be developed. Students will learn how to evaluate whether the information provided is sufficient to solve steady-state material balances frequently encountered in process design. Students will be exposed to both mathematical software as well as process modeling software useful for solving process engineering problems and when each should be utilized. Pre: 2114, MATH 2224. Co: ENGE 2324. (2H,2C) 2164: CHEMICAL ENGINEERING THERMODYNAMICS First and Second Laws, properties fluids, properties of homogeneous mixtures; phase equilibria, chemical-reaction equilibria. Pre: 2114. Co: CHEM 3615. (3H,3C)
2984: SPECIAL STUDY
Variable credit course.
3015-3016: PROCESS MEASUREMENT & CONTROL
3015: Common process measurements; applications to theory and practice of automatic control of chemical processes
3016: Design and laboratory practice underlying the automatic computer control of chemical processes. Pre: 2124; MATH 4564 or 4544. (3H,3C) 3016: 2124. (1H,3L,2C)
3034: DIGITAL PROCESS CONTROL
Principles underlying digital control algorithms and
digital process simulation; applications to the theory
and practice of digital process measurement and control.
Pre: 3016.
(2H,2C)
3044: HEAT TRANSFER One and two dimensional conduction, convection, and diffusion of thermal energy; heat transfer rates, steady state and unsteady state conduction, convection; design of heat exchangers; forced and free convection boiling and condensation. Pre: 2164, 3114, MATH 4564 or 4544. (2H,2C)
3114: FLUID TRANSPORT Fluid statics, surface tension, fluid dynamics, Newton's Law of viscosity, momentum transport, laminar and turbulent flow, velocity profiles, flow in pipes, flow around objects, non-Newtonian fluids, design of piping systems, pumps and mixing. Pre: 2114; PHYS 2305. Co: MATH 4564 or 4544. (3H,3C)
3134: SEPARATION PROCESSES Binary separations and multicomponent separations, distillation, batch distillation, extraction, absorption, McCabe-Thiele and Ponchon Savaret methods, short cut methods, design of plate columns, plate and column efficiencies. Pre: 2164; CHEM 3615 or 2164. (3H,3C) 3144: MASS TRANSFER
Multidimensional molecular diffusion and convection of single and multi-component systems; mass transfer rates; steady state, quasi-steady state and transient mass transfer; effect of reactions on mass transfer; convective mass transfer coefficients; design of stage and continuous gas/liquid contractors, membrane, liquid-liquid and liquid-solid separation processes, artificial kidney and drug delivery systems. Pre: 2164, 3114, MATH 4564 or 4544. (3H,3C) 3184: CHEMICAL REACTOR ANALYSIS AND DESIGN Power-law rate expressions, kinetic data, rate constants, Arrhenius equation, design of reactors, reactor behavior. Pre: 2164, MATH 2214 or 4544. Co: CHE 3044 and 3144. (3H,3C)
4014: CHEMICAL ENGINEERING LABORATORY Practical experience in the planning of experimentation, gathering of experimental data, interpretation of data, and the preparation of written and oral reports. Use of small scale processing equipment. Applications include momentum transfer, heat transfer, mass transfer, and chemical reaction. Use of automatic control and data acquisition. Pre: 3015, 3044, 3134, 3144, 3184; ENGL 3764 and grade of C- or better in all CHE prefix courses, in-major GPA of 2.0 or better. (15L,5C) 4034: CHEMICAL REACTION DESIGN Reactor design for multiple reactions, non isothermal operation, optimum reactor operation and configurations, design and analysis of heterogeneous reactors, mass transfer limitations. Pre: 3144, 3184. (3H,3C)
4044: APPLIED MATHEMATICS IN CHEMICAL ENGINEERING
Mathematical techniques applied to the solution of chemical
engineering problems.
Pre: 3134, 3144, 3184.
(2H,2C)
4064: PROCESS SYSTEMS ANALYSIS
Simulation and design of concatenated chemical engineering
operations utilizing digital and analog computation methods.
Pre: 4014.
(2H,3L,3C)
4104: PROCESS MATERIALS Basics of materials science as it relates to the interest of the chemical engineer. The course emphasizes the three fundamental areas of material science being polymer materials, metallics, and ceramic/inorganic glasses. The general molecular structure property - application behavior of each area will be presented but with a focus when possible on topics related to the field of chemical engineering. Pre: 2164; CHEM 2535 or 2565. (3H,3C) 4114: CHEMICAL MICROENGINEERING Application of principles of chemical engineering to small chemical systems. Topics include: conservation-of-species equation, linear multi-state chemical systems, unit micro-operations, rate and diffusion control, multi phase catalysis, chromatography, phase-transfer catalysis, facilitated diffusion. Pre: 3184. (3H,3C)
4134: CHEMICAL PROCESS MODELING Mathematical modeling of chemical processes, application of numerical techniques to the solution of equations, use of a programming language to write programs for calling numerical subroutines, numerical solutions of problems resulting in partial differential equations. Pre: 3144. Co: 3044, 3184 (2H,2C) I. 4144 (MKTG 4144): BUSINESS AND MARKETING STRATEGIES FOR THE PROCESS INDUSTRIES Business strategies and industrial marketing concepts, and their application in the chemical, pharmaceutical and related process industries. The course is designed for engineers and other students planning a career in the process industries. Junior standing required. Pre: ECON 2005. (3H,3C)
4185-4186: PROCESS AND PLANT DESIGN
Chemical process synthesis and plant design, economic analysis of alternative processes, process equipment design and specifications, computer-aided process design and simulation, design case studies, application of scientific and engineering knowledge to practical design problems. Pre: 4185: 3015, 3044, 3134, 3144, 3184; Co: 3184. Pre: 4186: 4185. Grade of C- or better in all CHE prefix courses, in-major GPA of 2.0 or better. (4H,4C) 4214 (MSE 4514): INTRODUCTION TO POLYMER MATERIALS Basics of polymeric materials including description and categorization of macromolecules; characterization; mechanical properties; rubbery, glassy, crystalline, and viscous flow behavior. Pre: CHEM 2536. (3H,3C)
4224 (MSE 4524): INTRODUCTION TO POLYMER PROCESSING Basic principles of momentum and heat transfer applied to the analysis of polymer processing operations. (3H,3C) 4304: APPLIED SURFACE AND COLLOID CHEMISTRY
A study of surface and colloid phenomena and their
application, especially in the chemical and chemical
engineering fields.
(3H,3C)
4314: TOPICS IN APPLIED CHEMISTRY The purpose of this course is to acquaint students of chemical engineering with some of the chemistry essentials to an understanding of the manufacture of important industrial chemicals, mostly in the inorganic chemical area. It will include a discussion of some of the principles involved in catalysis, applied electrochemistry, and separation methods. (3H,3C)
4324: FLUIDIZATION ENGINEERING
An introduction to fluid-particle systems. Basic
calculations of the subject are outlined, enabling the
student to understand the work published in the literature.
Introduction to the design of fluidized systems.
Pre: 3184.
(2H,2C)
I.
4544 (BSE 4544): PROTEIN SEPARATION ENGINEERING Concepts, principles and applications of various unit operations used in protein separations. Properties of biological materials, such as cells and proteins, and their influences on process design. Design of processes for protein purification based on the impurities to be eliminated. Concepts and principles of scale-up of unit operations. Case studies in practical protein recovery and purification issues, with a focus on enhanced protein purification by genetic engineering. Protein purification process simulation and optimization using process simulation software. Pre: BSE 3504 or CHE 3144. (3H,3C)
4904: PROJECT AND REPORT
Variable credit course.
4974: INDEPENDENT STUDY
Variable credit course.
4984: SPECIAL STUDY
Variable credit course.
4994: UNDERGRADUATE RESEARCH
Variable credit course.
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