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Title: BLOOMS TAXONOMY IN ENGINEERING EDUCATION


1
BLOOMS TAXONOMY IN ENGINEERING EDUCATION
  • Siti Rozaimah Sheikh Abdullah
  • Jabatan Kejuruteraan Kimia dan Proses
  • Fakulti Kejuruteraan dan Alam Bina

2
BLOOMS TAXONOMY
  • More than one type of learning3 domains
  • Cognitive development of intellectual skills.
  • Affective manner in which we deal with things
    emotionally (feelings, values, attitudes).
  • Psychomotor physical movement, coordination,
    motor-skill areas.
  • Bloom developed taxonomy (hierarchy) of Cognitive
    learning skills
  • Allows educators to evaluate learning of
    students systematically

3
Blooms Taxonomyof Cognitive Learning Skills
6
5
4
3
2
1
4
Details on Blooms Taxonomy
  • Knowledge - repeating verbatim
  • List
  • State
  • Comprehension - demonstrating understanding of
    terms and concepts
  • Explain in your own words
  • Interpret
  • Application - applying learned information to
    solve a problem
  • Calculate
  • Solve

Higher thought processes
5
Details on Blooms Taxonomy
  • Analysis - breaking things down into their
    elements, formulating theoretical explanations or
    mathematical or logical models for observed
    phenomena
  • Derive
  • Explain
  • Synthesis - creating something, combining
    elements in novel ways
  • Formulate
  • Make up
  • Design

Higher thought processes
6
Details on Blooms Taxonomy
  • Evaluation - making and justifying value,
    judgments or selections from among alternatives
  • Determine
  • Select
  • Critique

Higher thought processes
7
Application in Engineering Education
  • Creativity is very important for the engineering
    profession.
  • Creativity requires higher thought processes
    (Bloom items 4-6 Analysis, Synthesis,
    Evaluation).
  • In many cases lectures and homework assignments
    focus exclusively on Bloom item 3 Application.
  • Then, if they put a high-level question on exam
    and the students do poorly on it, they blame the
    students lack of ability or poor study habits.
  • Need to include high-level tasks in learning
    outcomes.

8
Application in Engineering Education
  • Need to develop high level tasks
  • Include high-level tasks in learning outcomes
  • Share them with students
  • Practice them in class
  • Practice via assignments
  • Test on examination

9
COURSE OUTCOMES
  • Need to identify relevant COs according to
    Blooms Taxonomy.
  • Eg. of COs for KF1084 Introduction to Engineering
    Thermodynamics
  • understand the basic concepts of thermodynamics
    such as temperature, pressure, system,
    properties, process, state, cycles and
    equilibrium.
  • conduct experiments regarding the measurement and
    calibration of temperatures and pressures in
    groups.
  • identify the properties of substances on property
    diagrams and obtain the data from property
    tables.
  • understand the energy transfer through mass, heat
    and work for closed and control volume systems.
  • apply the first Law of Thermodynamics on closed
    and control volume systems.
  • apply Second Law of Thermodynamics and entropy
    concepts in analyzing the thermal efficiencies of
    heat engines such as Carnot and Rankine cycles
    and the coefficients of performance for
    refrigerators.
  • apply basics of heat transfer through steady
    state conduction, natural and forced convection
    and radiations.

10
LEARNING OUTCOMES
  • Should elaborate the learning outcomes in the
    beginning of a topic.
  • Students should know what are the expectation of
    the lecturer from them.
  • Eg. of 1st Year learning outcomes
  • understand the concept of a pure substance.
  • describe the physics of phase-change processes
    and illustrate on property figures such as P-v
    and T-v diagrams.
  • determine thermodynamic properties of pure
    substances from tables of property data.
  • understand the hypothetical substance ideal gas
    and apply the ideal-gas equations of state and
    the compressibility factor that accounts for the
    deviation of real gases from ideal-gas behavior.
  • Understand the concepts of specific heat,
    internal energy and enthalpy.

11
EXAMINATION QUESTIONS
  • 1st Year Course
  • Figure 3 shows a refrigerator in which R-134a
    acts as the working fluid. The refrigerator
    operates in an ideal vapour-compression
    refrigeration cycle between 0.14 and 0.8 MPa.
  • a. State the reasons why the vapour-compression
    refrigeration cycle cannot be classified as an
    internally reversible cycle.
    (4 marks)
  • b. Show the refrigeration cycle on a T-s diagram
    using symbols as shown in the figure.


  • (2 marks)
  • c. If the mass flow rate for the refrigerant is
    0.05 kg/s, determine
  • i. the heat removal from the cold space and the
    required power input to the compressor,

    (6 marks)
  • ii. the heat removal to the surroundings,
    (4 marks)
  • iii. COP for the above refrigeration cycle,
    (4 marks)
  • iv. COP for the cycle if the expansion valve is
    replaced by an isentropic turbine. Is this value
    larger or smaller than that of part (iii)? Give
    reasons.


  • (5 marks)

12
LEARNING OUTCOMES
  • Eg. of 2nd Year learning outcomes
  • understand and know how to derive and apply
    Maxwell equation.
  • apply Clausius/Clayperon in two-phase systems.
  • apply equations of state (EOS) such as Peng
    Robinson (PR), Redlich-Kwong (RK),
    Soave-Redlich-Kwong (SRK), Van der Waals (VdW)
    and virial equations in order to determine the
    properties of liquids and gases.
  • determine residual properties of gases and
    liquids.

13
EXAMINATION QUESTIONS
  • 2nd Year Course

14
COURSE OUTCOMES
  • Eg. of 3rd Year course outcomes
  • Understandings on basic concepts of mechanical
    design of pressure vessels.
  • Able to relate the principles of stress, strain,
    in designing domed ends.
  • Knowledge on design parameters of process
    equipment construction design pressure and
    temperature, materials selections, failure
    theories, corrosion loads, design loads,
    corrosion allowance.
  • Able to determine minimum practical wall
    thickness of pressure vessels (spherical or
    cylindrical) and head and closures
    (hemispherical, torispherical, ellipsoidal, cone,
    torus) under internal and external pressure
    according to ASME codes.
  • Able to design pressure vessels under loadings of
    dead weight, winds, earthquake, torque according
    to ASME codes.
  • Able to design vessel supports under combined
    loadings and bolted flanged joints based on ASME
    codes.
  • Able to prepare engineering graphics of
    mechanical design of pressure vessels.

15
EXAMINATION QUESTIONS
  • 3rd Year Course

16
REFERENCES
  • S. Goel and N. Sharda, What do engineers want?
    Examining engineering education through Blooms
    Taxonomy, 15th Annual Conference for the
    Australian Association for Engineering Education,
    AaeE2004, Sep 2004, Toowoomba, Queensland
    Australia.
  • S. Goel, What is High About Higher Education?
    The National Teaching and Learning Forum, Volume
    13, Number 4, 2004.
  • R.M. Felder, R. Brent, The ABCs of Engineering
    Education ABET, Blooms Taxonomy, Cooperative
    Learning, and So On, Session 1375, Proceedings
    of the 2004 American Society for Engineering
    Education Conference and Exposition, Salt Lake
    City, UT, June 2004.
  • Benjamin S. Bloom in Blooms Taxonomy A
    Forty-Year Retrospective, edited by L.W.
    Anderson, University of Chicago Press, 1994.
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