Facilities Engineering
Technology Courses
ALL COURSES ARE GRADED USING
THE
A–F SYSTEM UNLESS OTHERWISE
SPECIFIED.
Cooperative
Education
CEP 270. FET CO-OP I
CREDIT: 8
Prerequisites: CRU 150,
Sophomore Class Standing
This course is the first of two
summer co-ops required for the
Facilities Engineering
Technology major. It requires
the student to work in industry
under a cooperative education
training agreement by working
onsite for a 2-month period.
Students will encounter current
and practical work experience
with various facilities.
CEP 370. FET CO-OP II
CREDIT: 8
Prerequisites: CEP 270,
Junior Class Standing
CEP 370 is the second and final
of two summer cooperative
education courses required by
the Facilities Engineering
Technology Program. This course
requires the student to work in
industry under a cooperative
education training agreement by
working onsite for a 2-month
period. Students will encounter
current and practical work
experience with various
facilities.
CEP 390. INDEPENDENT STUDY
CEP 395. SPECIAL TOPICS
Chemistry
CHE 205. CHEMISTRY OF PLANT
PROCESSES
CLASS HOURS: 3, CREDIT: 3
Prerequisites: CHE 100, CHE 100L
This course examines the role
that water plays in both
production and power plant
processes. Emphases within the
course focus on the nature of
liquid mixtures, including
equilibrium concepts as they
relate to solution chemistry,
sources and types of organic and
inorganic water contamination,
the quantification of water
contamination and the
pre-treatment and post-treatment
of water utilized in plant
processes.
CHE 390. INDEPENDENT STUDY
CHE
395. SPECIAL TOPICS
Computers
COM 220. PROGRAMMING
APPLICATIONS
FOR ENGINEERING TECHNOLOGY
MAJORS
CLASS HOURS: 1, CREDIT: 1
Corequisite: COM 220L
This course is designed to
instruct Engineering Technology
students in the skills needed to
utilize the basic operations of
calculators and computers in a
modern engineering environment.
The scope of this course will
range from simple calculations
commonly found in engineering
applications to the more complex
operations necessary to evaluate
physical phenomena in the real
world. The reduction of physical
data and basic functions to
graphical representations will
be explored in full using both
calculators and computers.
COM 220L. PROGRAMMING
APPLICATIONS FOR ET MAJORS LAB
LAB HOURS: 2, CREDIT: 1
Corequisite: COM 220
Supports the instruction in COM
220 by providing actual
experience in engineering
problem solutions using computer
applications. This lab uses
various common computer
applications, such as Microsoft
Excel, to analyze engineering
situations, perform data
manipulation, solve problems,
and analyze graphs. The
programming environment of Visual Basic
for Applications (VBA)
is used to write programs to
perform engineering analysis.
COM 390. INDEPENDENT STUDY
COM
395. SPECIAL TOPICS
Cruise
CRU 150. SEA TRAINING I
(ENGINE)
CREDIT: 8
Prerequisites: DL 105, DL 105L,
EPO 110,
EPO 120, EPO 120L
First at-sea experience on the
training ship. Introduction to
the fundamentals of engineering
systems operations and shipboard
routine, including operation and
monitoring techniques for diesel
propulsion, electrical power
generation, and evaporators and
support equipment. Duties during
emergency situations such as
fire, abandon ship, and rescue
are also learned. By the end of
the cruise, the student will
have demonstrated the required
STCW competencies and understand
basic power plant operation and
maintenance.
CRU 390. INDEPENDENT STUDY
CRU
395. SPECIAL TOPICS
Engineering
ENG 100. ENGINEERING GRAPHICS
CLASS HOURS: 2, CREDIT: 2
Prerequisite: None
Introduction to engineering
graphics, the primary media for
developing and communicating
engineering system design
information. Preparation of
technical drawings using
drafting instruments and
computer-aided design (CAD)
software is based on ANSI
standards and includes
orthographic projections,
dimensioning, and tolerances.
ENG 470. ENGINEERING MANAGEMENT
CLASS HOURS: 3, CREDIT: 3
Prerequisite: Junior Class
Standing
Begins with a brief introduction
to the engineering profession
and then focuses on total
quality management, personnel
management and communications,
project management, and legal
concerns. Topics such as
professional liability and
ethics will provide the student
with a sense of his or her
responsibility. In addition,
numerous case studies enhance
student understanding.
ENG 472. FACILITIES MANAGEMENT
CLASS HOURS: 3, CREDIT: 3
Prerequisite: None
Topics from various engineering
and technology disciplines are
covered and integrated into a
structure consistent with the
understanding and experiences
needed in the facilities
engineering management
profession. This course is the
introductory course to the
Facilities Engineering
profession. In their
senior year, students must take
and pass a comprehensive
examination administered by an
independent agency as designated
by the engineering technology
faculty.
ENG 390. INDEPENDENT
STUDY
ENG 395. SPECIAL TOPICS
Engineering
Plant Operations
EPO 110. PLANT OPERATIONS I
LAB HOURS: 3, CREDIT: 1
Prerequisite: None
A laboratory class directly
involved in the inspection,
maintenance, and repair of
marine machinery and systems
aboard the training ship.
Emphasis is the safe and proper
use of hand and power tools and
the identification and repair of
valves, pumps, fittings, piping,
switches, controllers, and
circuit breakers. Lab
reports will be completed on
work performed.
EPO 120. INTRODUCTION TO MARINE
ENGINEERING SYSTEMS
CLASS HOURS: 2, CREDIT: 2
Prerequisite: None
Corequisite: EPO 120L
Analysis and understanding of
shipboard diesel power plants,
including the diesel cycle,
engine components, and support
systems, together with
lubricating oil, fuel oil
supply, and cooling water
systems. Analysis and study of
shipboard steam power plants
including the Rankine cycle with
superheat and Rankine cycle
components, including turbine,
boilers, condensers, and pumps.
EPO 120L. INTRODUCTION TO MARINE
ENGINEERING SYSTEMS LAB
LAB HOURS: 2, CREDIT:
1
Corequisite: EPO 120
This lab studies
primary engineering systems
aboard the Training Ship
Golden Bear. Topics of study
include shipboard
familiarization; measurement
methods; main engine jacket
water system; fuel oil storage,
transfer and supply; fuel oil
injection systems; lube oil
system; gear train and clutch;
cooling water systems;
environmental protection
systems; starting air system;
distillation plant; and basic
shipboard firefighting and
safety. Students are given
engineering system tracing
assignments including main
engine jacket water system, main
engine fuel supply system, main
engine lubricating oil system,
central fresh water cooling
system, and main engine starting
air system.
EPO 130 AUXILIARY MACHINERY
CLASS HOURS: 2, CREDIT: 2
Prerequisites: EPO 120, EPO 120L
Theory, operation, and
maintenance of power plant
auxiliary equipment. Topics
include piping systems, manual
and automatic control valves,
centrifugal and positive
displacement pumps, packing and
mechanical seals.
EPO 210. PLANT OPERATIONS II
LAB HOURS: 3, CREDIT: 1
Prerequisite: EPO 110
Continuation of the practical
work performed on the training
ship or in facilities
maintenance lab. Equipment
maintenance is emphasized with
work on diesel engines, air
compressors, generators,
electrical equipment and pumps.
Lab reports will be completed on
work performed.
EPO 213. WELDING LAB
LAB HOURS: 3, CREDIT: 1
Prerequisite: None
A laboratory course that
provides the experience in
welding, brazing, cutting, and
burning techniques sufficient to
effect emergency repairs and
routine maintenance of
engineering structures and
systems.
EPO 214. BOILERS
CLASS HOURS: 3, CREDIT: 3
Prerequisites: EPO 120, EPO 120L
Corequisite: EPO 230
Comprehensive study of fossil
fuel steam generators, with
emphasis on marine propulsion
plants. Studies include the
principles of boiler design and
construction, boiler
auxiliaries, principles of
combustion, heat recovery
equipment, automated boiler
controls, and boiler water
treatment. American Bureau of
Shipping, U.S. Coast Guard, and
ASTM/ASME standards are
referenced throughout. In
addition, the course prepares
students for the steam plant
section of the U.S. Coast Guard
Third Assistant Engineer’s Exam.
EPO 215. MANUFACTURING PROCESSES
I
LAB HOURS: 3, CREDIT: 1
Prerequisite: None
An introduction to machine shop
practices utilizing engine
lathes and milling machines,
precision measuring instruments
and hand tools. Assigned
projects include execution of
designs developed by students in
prior graphics design courses.
EPO 220. DIESEL ENGINEERING I
CLASS HOURS: 2, CREDIT: 2
Prerequisite: None
Introduction to the internal
combustion engine utilized by
industry and merchant vessels.
Covered topics include basic
theory, history of the diesel
engine, gas exchange process,
engine types, engine
construction, engine parts, fuel
injection, and merchant vessel
propulsion. All diesel engine
types are covered but emphasis
is given to the crosshead type
slow-speed diesel engine which
is the dominant form of main
propulsion for the world’s
merchant fleet. The course
prepares students for the motor
section of the USCG Third
Assistant Engineer’s
examination.
EPO 230. STEAM PLANT SYSTEM
OPERATIONS
LAB HOURS: 2, CREDIT: 1
Prerequisites: EPO 120, EPO 120L
Corequisite: EPO 214
A hands-on learning experience
in the Steam Plant Simulator.
An introduction to the
engineering systems, operating
and casualty procedures, and
watch requirements of a steam
propulsion plant.
EPO 235. STEAM PLANT WATCH TEAM
MANAGEMENT
LAB HOURS: 2, CREDIT: 1
Prerequisites: EPO 214, EPO 230
Corequisite: EPO 312
A hands-on learning experience
in the Steam Plant Simulator.
Develops fault analysis
techniques for steam propulsion
plants, communication skills in
a work environment, and
management abilities.
EPO 310. PLANT OPERATIONS III
LAB HOURS: 3, CREDIT: 1
Prerequisite: EPO 210
A continuation of the practical
work performed on the training
ship or in facilities
maintenance lab. Supervision of
equipment maintenance is
emphasized. The students rotate
in working on main propulsion,
electrical and auxiliary
equipment. Lab reports will be
completed on work performed.
EPO 312. TURBINES
CLASS HOURS: 3, CREDIT: 3
Prerequisites: EPO 214, EPO 230
Corequisite: EPO 235
Comprehensive study of steam
turbines, condensers, reduction
gears, propulsion shafting, and
gas turbines, with emphasis on
marine propulsion plants. Steam
and gas turbine controls and the
thermodynamic principles of
efficient steam plant operation
are also included. Through the
course, students will gain the
knowledge to operate and
maintain turbines and their
auxiliary systems. In addition,
the course prepares students for
the steam plant section of the U.S.
Coast Guard Third Assistant
Engineer’s Exam.
EPO 315. MANUFACTURING PROCESSES
II
LAB HOURS: 3, CREDIT: 1
Prerequisite: EPO 215
A continuation of EPO 215 Manufacturing
Processes I, emphasizing work on
metal lathes and vertical milling
machines.
EPO 319. FACILITIES ENGINEERING
DIAGNOSTICS LAB
LAB HOURS: 2, CREDIT: 1
Prerequisite: None
Examines the theory and
application to machinery
maintenance of vibration
analysis, oil analysis,
machinery alignment,
thermography, and overall plant
performance analysis. Includes
the study of various machinery
maintenance programs applied to
facilities engineering systems,
including machinery history,
trend analysis, and predictive
maintenance.
EPO 321. DIESEL PLANT SIMULATOR
LAB HOURS: 2, CREDIT: 1
Prerequisite: EPO 220
This course provides an
introduction to the operation of
slow-speed diesel propulsion
systems. The course consists of
lecture and practical training
in engineering systems and
proper operating procedures. The
student will learn to operate a
heavy-fuel diesel-propulsion
plant under normal operating
conditions. Students will learn
to work effectively as a team to
diagnose combustion and
machinery faults under emergency
conditions representative of
those encountered on an
operating vessel. This course
will emphasize Engine Team
Management techniques utilizing
the simulator as an
instructional tool to train the
students in good communications
and problem solving even during
stressful conditions.
EPO 390. INDEPENDENT STUDY
EPO 395. SPECIAL TOPICS
EPO 413. ADVANCED WELDING AND
FABRICATION
Prerequisites: EPO 213, EPO 215
A practical experience in taking
a fabrication project through
each step to completion.
Scheduling, drawings, materials
lists, various fabricating
techniques, and teamwork are all
part of the assigned project.
Engineering
Technology
ET 110. INTRODUCTION TO
ENGINEERING
TECHNOLOGY
CLASS HOURS: 1, CREDIT: 1
A survey course introducing the
engineering technology
profession and curriculum.
Topics in engineering education,
academic success strategies, and
career opportunities are
covered. Also, the basic
concepts of engineering analysis
are introduced through the use
of engineering units and
significant features in
calculations. Field trips are
utilized to give the students
exposure to their chosen
profession.
ET 230. PROPERTIES OF MATERIALS
CLASS HOURS: 2, CREDIT: 2
Prerequisites: None
Corequisite: ET 230L
Examination of the properties of
materials from the atomic to the
molecular levels, looking at
crystal structures and the
application of materials to
engineering systems. Emphasis is
on metals, but nonmetals are
discussed. Mechanical
properties, creep, fatigue,
corrosion and failure
characteristics are covered.
Current usage of advanced
materials is also discussed.
ET 230L. PROPERTIES OF MATERIALS
LAB
LAB HOURS: 2, CREDIT: 1
Prerequisites: None
Corequisite: ET 230
Investigates the physical
characteristics of materials
through testing, data
acquisition, and calculations.
Tests conducted include tensile,
fatigue, creep, impact energy,
and hardenability. Students
learn how the properties
described in ET 230 are derived.
ET 232. STATICS
CLASS HOURS: 3, CREDIT: 3
Prerequisites: MTH 200, PHY 100,
PHY 100L
Force systems and the conditions
of equilibrium for particles and
rigid-bodies are studied in two
and three dimensions. The
principles of equilibrium,
moments, and dry friction are
applied to engineering system
components and structures.
ET 250. ELECTRICAL CIRCUITS
CLASS HOURS: 3, CREDIT: 3
Prerequisite: MTH 201, PHY 105
Corequisite: ET 250L
Principles and applications of
DC and AC circuit analysis, node
and mesh equations, Thevenin
equivalent circuits, maximum
power transfer, first order
transients, simple filters,
phasors, power, power factor,
and relative power in
single-phase systems.
ET 250L. ELECTRICAL CIRCUITS LAB
LAB HOURS: 2, CREDIT: 1
Corequisite: ET 250
Application of circuit
elements and principles from ET 250 in
laboratory measurements and
analysis.
ET 330. DYNAMICS
CLASS HOURS: 3, CREDIT: 3
Prerequisite: ET 232
Motion and force analyses for
particles and rigid-bodies are
studied in two and three
dimensions. The principles of
dependent and relative motion,
work and energy, conservation of
energy, and impulse and momentum
are applied to engineering
systems components.
ET 332. STRENGTH OF MATERIALS
CLASS HOURS: 3, CREDIT: 3
Prerequisites: ET 230, MTH 201
Study of basic concepts in
strength of materials: normal,
shear, bending, and bearing
stress; stress-strain relation;
and design properties of
materials. Practical application
of structure calculations for
sizing bolts, rivets, shafts,
beams, columns, and pressure
vessels.
ET 340. FLUID MECHANICS
CLASS HOURS: 3, CREDIT: 3
Prerequisites: MTH 200, PHY 100,
PHY 100L
Corequisite: ET 340L
The application of principles of
incompressible fluid flow.
Topics include forces in static
fluids and fluids in motion,
applications of Bernoulli’s
equation, pressure losses in
pipe systems, open channel
flows, pump selection, and air
flow in ducts.
ET 340L. FLUID MECHANICS LAB
LAB HOURS: 2, CREDIT: 1
Corequisite: ET 340
ET 342. REFRIGERATION AND AIR
CONDITIONING
CLASS HOURS: 2, CREDIT: 2
Prerequisite: ET 344
Corequisite: ET 342L
Introduction to basic
refrigeration and air
conditioning principles and
equipment. Included are the
theory and application of direct
and indirect refrigeration
cycles commonly found on
merchant ships and ashore
including main cargo freezers,
air conditional systems, chill
water systems, absorption
systems, refrigerated vans, and
ice machines.
ET 342L. REFRIGERATION AND AIR
CONDITIONING LAB
LAB HOURS: 2, CREDIT: 1
Corequisite: ET 342
ET 344. THERMODYNAMICS
CLASS HOURS: 3, CREDIT: 3
Prerequisites: PHY 100, PHY 100L,
MTH 200
Basic laws of thermodynamics and
their applications to heat-power
machinery applied on shipboard
heat-power plants, steam and gas
turbines, internal combustion
engines, and vapor-compression
refrigeration systems.
ET 350. ELECTRICAL MACHINERY
CLASS HOURS: 3, CREDIT: 3
Prerequisites: ET 250, ET 250L
Corequisite: ET 350L
Principles and application of
magnetic circuits and
transformers, three phase power,
power factor correction, DC
motors and generators, three
phase AC motors and alternators,
single-phase motors, stepper
motors, electronic motor
control, and circuit protection
devices.
ET 350L. ELECTRICAL MACHINERY
LAB
LAB HOURS: 2, CREDIT: 1
Prerequisites: ET 250, ET 250L
Corequisite: ET 350
Application of the principles
from ET 350 in laboratory
measurements and analysis.
ET 370. ELECTRONICS
CLASS HOURS: 3, CREDIT: 3
Prerequisites: ET 250, ET 250L
Corequisite: ET 370L
Principles and application of
electronic circuits and
components, microcontrollers,
operational amplifiers,
comparators, peak detectors,
active filters, timer circuits,
AD conversion, serial
communication, and micro
electro-mechanical systems.
ET 370L. ELECTRONICS LAB
LAB HOURS: 2, CREDIT: 1
Corequisite: ET 370
Application of the principles
from ET 370 in laboratory
measurements and analysis,
followed by a comprehensive
team project.
ET 390. INDEPENDENT STUDY
ET
395. SPECIAL TOPICS
ET 400. INSTRUMENTATION AND
MEASUREMENT
CLASS HOURS: 3, CREDIT: 3
Prerequisites: COM 220, COM
220L, ET 370, ET 370L, MTH 201
Corequisite: ET 400L
A study of instrumentation
devices and their uses in
monitoring processes.
Instrumentation used for
measuring temperature, pressure,
level, flow, position and motion
as well as other types of
analytical measurement are
studied. In addition to
instrumentation, the principles
of signal conditioning are also
studied including op-amp
applications, filtering,
applications to pneumatic
systems, and digital signal
conditioning. Concludes with a
study of how instrumentation
relates to modern data
acquisition systems; how to
optimize measurements and
effectively analyze measured
signals. Laboratory applications
are investigated concurrently
with course topics.
ET 400L. INSTRUMENTATION AND
MEASUREMENT LAB
LAB HOURS: 2, CREDIT: 1
Prerequisites: COM 220, COM
220L, ET 370, ET 370L, MTH 201
Corequisite: ET 400
This lab is designed to study
principles introduced in ET 400
Instrumentation and Measurement.
Lab procedures include studies
involving signal conditioning,
Wheatstone bridge applications,
use of operational amplifiers
for signal conditioning, Boolean
logic, thermal transducers,
strain gage measurements,
variable capacitance
transducers, and optical
transducers. Computer-based data
acquisition methods are used in
all the procedures.
ET 442. HEATING, VENTILATION,
AND AIR
CONDITIONING
CLASS HOURS: 2, CREDIT: 2
Prerequisites: ET 342, ET 342L
Corequisite: ET 442L
This is the final course in a
two course series of applied
thermodynamics with regards to
refrigeration/air conditioning
cycle. This course will focus on
the HVAC requirements of
facilities with application to
ships as well as any facility.
Designing of HVAC systems,
including heat balance, duct
design and fan selection will be
used to examine the system
requirements and to examine
potential modification to the
existing system. The course will
prepare the student for the
Certified Plant Engineer–In
Training (CPE-IT), Fundamentals
of Engineering (FE), and United
States Coast Guard (USCG) exams.
ET 442L. HEATING, VENTILATION,
AND AIR
CONDITIONING LAB
LAB HOURS: 2: CREDIT: 1
Prerequisites: ET 342, ET 342L
Corequisite: ET 442
ET 452. ELECTRICAL DISTRIBUTION
AND
TRANSMISSION
CLASS HOURS: 3, CREDIT: 3
Prerequisites: ET 350, ET 350L,
ET 370,
ET 370L
This course, building on a basis
of electric circuits and
machines, addresses the role of
electric power transmission and
distribution as applied to
typical plant facilities and
processes. Distribution layout,
transformers, distribution
equipment, and substations are
covered. Also, transmission
systems and transmission lines
are studied.
ET 460. AUTOMATION
CLASS HOURS: 3, CREDIT: 3
Prerequisites: ET 400,
ET 400L,
MTH 201
Corequisite: ET 460L
A study of automation in power
plants, engineering processes,
and manufacturing processes
leading to an understanding of
modern control systems.
Principles of analog and digital
control systems are studied, as
well as measurement methods and
final control valves and
actuators. PID (proportional
plus integral plus derivative)
control applications and
programmable logic controllers
are also studied. Modeling,
measurement and control of
mechanical, thermal, fluid, and
electrical systems are
investigated.
ET 460L. AUTOMATION LAB
LAB HOURS: 2, CREDIT: 1
Prerequisites: ET 400, ET 400L,
MTH 201
Corequisite: ET 460
This lab is designed to study
principles introduced and
discussed in ET 460. Lab
procedures include introduction
to the concepts of closed loop
control, PLC (programmable logic
controllers) programming,
pneumatic logic and control
applications, a study of
frequency response in systems
(Bode plots), and process loop
tuning methods.
ET 490. POWER ENGINEERING
TECHNOLOGY
CLASS HOURS: 2, CREDIT: 2
Prerequisites: ET 340, ET 340L,
ET 344
Corequisite: ET 490L
Capstone course in engineering
technology. Engines in labs,
simulators, and operating power
plants are used to explore the
application of thermodynamics,
fluid mechanics, and controls to
operating systems. Students are
required to develop and carry
out analytical procedures to
evaluate the effects of changing
parameters on operating power
plants.
ET 490L. POWER ENGINEERING
TECHNOLOGY LAB
LAB HOURS: 2, CREDIT: 1
Prerequisites: ET 340, ET 340L,
ET 344
Corequisite: ET 490
Humanities
HUM 310. ENGINEERING ETHICS
CLASS HOURS: 3, CREDIT: 3
Prerequisites: EGL 200, Junior
or Senior
Class Standing
Addresses the major concepts of
ethics as applied to the
discipline and practice of
engineering. Topics include the
scope and aims of engineering
ethics, moral reasoning and
ethical theories, engineering
and society, ethics and the law,
the engineer’s responsibility
for safety, engineers and the
corporation, conflict of
interest/crime in the workplace,
rights of engineers/rules of
professional conduct, ethics,
global ethical issues involving
the engineering community,
engineering ethics in the
computer age, environmental
ethics, engineers as managers
and leaders, engineers as expert
witnesses, and steps to
principled reasoning/common
rationalizations. |
