Associate of Pre-Engineering | 69 credits minimum
Natural Sciences and Engineering Division
Taylorsville Redwood Campus SI 241
General Information 801-957-4944
Program Information 801-957-4418
Program Website
Academic and Career Advising
Program Faculty
Professors - Lee Brinton, Holly Moore, Nick Safai
Associate Professors - Sara Farida
Assistant Professors - Joel Clarkson, Quentin McRae, Rex Richards, Wesley Sanders, James Smith
Program Description
Chemical engineering emphasizes physical, life and engineering sciences to convert raw materials into necessary materials and energy systems.
Career Opportunities
Chemical engineers work in a wide range of industries, including petroleum processing, chemical processing and biomedical manufacturing, and in the development of new products based on chemical processes.
Transfer/Articulation InformationThe associate of pre-engineering degree in Chemical Engineering is a transfer degree similar to the associate of science degree, but has reduced General Education requirements. Current Accreditation Board of Engineering and Technology (ABET) standards require upper-division General Education courses. Engineering students who complete this degree may apply for advanced-placement at an engineering school, but must complete General Education requirements at the senior institution.
Estimated Cost for Students
Tuition and student fees: http://www.slcc.edu/student/financial/tuition-fees.aspx
Engineering textbooks can be very expensive and range from $30 to $300 apiece. The cost can be minimized by planning ahead to purchase used books or approved back editions. Plan on $300 to $500 per semester for textbooks and course fees.
Estimated Time to Completion
4 to 6 semesters depending on student preparation. Students who do not enter the program ready to take MATH 1210 (Calculus I) will require extra time.
Program Entry Requirements
The Chemical Engineering program requires as a prerequisite a science-oriented high school curriculum which includes as much mathematics, chemistry, physics and English as possible. Students who do not qualify to enter MATH 1210 , CHEM 1210 and ENGL 1010 should take prerequisite courses before entering the first semester of their program. Students who need to take preparatory courses to meet the requirements of first semester courses should plan on extra time to complete the program. Consult with the academic advisor concerning these courses. It is the student’s responsibility to examine each course description for details of prerequisite courses. Those prerequisites must be satisfied before the designated class may be taken.
Program Student Learning Outcomes |
Related College-Wide Student Learning Outcomes |
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1 - Acquire substantive knowledge
2 - Communicate effectively
3 - Develop quantitative literacies
4 - Think critically and creatively
5 - Develop knowledge and skills to be civically engaged
6 - Develop the knowledge and skills to work with others in a professional and constructive manner
7 - Develop computer and information literacy |
Be prepared for further study in Chemical Engineering or a related discipline at a four-year college or university by completing a course of study comparable to that required in the first 2 years at the University of Utah.
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1
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Demonstrate an understanding of the fundamentals of physical science, in particular inorganic chemistry, organic chemistry and physics, and the fundamentals of process engineering.
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1
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Demonstrate competence in both creating and interpreting engineering drawings, using modern computer tools and resources.
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2, 7
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Demonstrate an understanding of the mathematical tools necessary to perform engineering calculations - in particular Vector Calculus, Linear Algebra and Differential Equations.
Use these mathematical tools and strategies to solve engineering problems.
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3
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Solve complex problems in engineering and science using critical thinking skills and an effective problem solving strategy.
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4
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Demonstrate the laboratory skills necessary to design and perform scientific and engineering experiments. Interpret experimental data.
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3, 4
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Demonstrate an understanding of the environmental and social impact of engineering activities and the techniques required to mitigate those impacts.
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5
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Demonstrate an understanding of the ethical impacts of engineering decisions and the requirements for ethical behavior of an engineering professional.
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6
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Develop engineering computing skills, and use them to solve problems.
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7
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Demonstrate competence in technical report writing, other written communication and in oral communication of technical concepts.
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2
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