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What Engineers Know and How They Know It

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What Engineers Know and How They Know It Summary by David E. Goldberg University of Illinois at Urbana-Champaign deg_at_uiuc.edu Text Vincenti, W. G. (1990). – PowerPoint PPT presentation

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Title: What Engineers Know and How They Know It


1
What Engineers Know and How They Know It
  • Summary by David E. Goldberg
  • University of Illinois at Urbana-Champaign
  • deg_at_uiuc.edu

2
Text
  • Vincenti, W. G. (1990). What engineers know and
    how they know it Analytical studies from
    aeronautical history. Baltimore, MD Johns
    Hopkins University Press.

3
Engineering is Just Applied Science
  • 1922 Aeroplanes are not designed by science,
    but by art in spite of some pretence and humbug
    to the contrary.
  • Historians of technology have split off from
    historians of science
  • View science and technology as two categories,
    related but distinguishable.

4
Goal of Engineering Design
  • Normal design (by analogy to Kuhns normal
    science).
  • Versus radical design.
  • Design of artifacts as social activity

5
Design and Growth of Knowledge
  • B-24 airfoil design
  • Planform and airfoil
  • Consolidated Aircraft Corp.
  • Inventor David R. Davis.
  • Adopted and credited with B-24 long range.
  • Not in the main stream of airfoil thought.

6
Air Foil Evolution of Knowledge
  • Separation of planform and section.
  • Geometry first
  • Laminar v. turbulent boundary layer
  • Prolong laminar BL
  • Pressure distribution first
  • Analytical calculations based on conformal
    mapping.

7
Drivers of Knowledge
  • Decrease uncertainty
  • Increased performance presumptive anomaly, when
    science indicates better result is possible
  • Functional failure subjected to ever greater
    demands, applied in new situations.
  • Process Selection and variation.

8
Establishment of Design Requirements
  • Problem Flying quality specification.
  • Longitudinal stability
  • What stability and control characteristics
    needed?
  • How proportion aircraft to obtain?
  • Early schools of thought
  • Chauffeurs vs. airmen
  • Inherent stability vs. active control.

9
Early Aircraft
  • Sopwith Camel, Curtis JN-4, Thomas Morse S-4C,
    longitudinally unstable.
  • Qualitative description of early aircraft
    followed in end by detailed specs.

10
7 Elements
  • Familiarization with artifact and recognition of
    problem.
  • ID of basic variables derivation of concepts
    and criteria.
  • Development of instruments and technique.
  • Growth of opinion regarding desirable
    qualitities.
  • Development of practical scheme for research.
  • Measurement of characteristics for cross section
    of artifacts.
  • Assessment of results.

11
Theoretical Tool for Design
  • Example Control volume models.
  • Bernoulli as forerunner.
  • Karman Prandtl Modern usage.
  • Useful to engineers not physicists.
  • Creation of artifacts dictates different choice
    of tools.

12
Engineering Science v. Science
  • Similarities
  • Conform to same natural laws.
  • Diffuse by same mechanisms.
  • Cumulative facts build on facts.
  • Differences
  • ES create artifacts. S understand nature
  • Skolimowski technological progress pursuit of
    effectiveness in producing objects of given kind.

13
Data for Design
  • Case Durand propeller tests at Stanford,
    1916-26.
  • History
  • Smeaton Waterwheel studies of 1759, systematic
    experiment scale models.
  • Froude testing of ship hulls 1868-1874.
  • Reynolds 1883.
  • Dimensional analysis Fourier (early 1800s),
    Rayleigh (late 1800s)

14
Parameter Variation
  • Via experimental or theoretical means.
  • Via experimental means is not peculiar to
    engineering.
  • Immediate interest in data for design, longer
    term interest in establishing a theory.
  • Produce data in absence of theory.
  • Indispensable for creation of such data.
  • Absence of theory a number of causes.
  • Scale models not necessary.
  • Optimization often part of the experimentation.

15
Design and Production
  • Case Invention of flush riveting.
  • Innovation driven by aerodynamics.
  • Caused changes in production.
  • Bigger gains first (retractable gear, flaps).
  • 160,000 to 400,000 rivets per plane.

16
Dimpled Riveting
  • Science played no role in the story.
  • Each company pursued own program.
  • Different types of knowledge
  • Explicit
  • Tacit

17
Problems Within Technology
  • Internal logic of technology
  • Physical laws
  • Practical requirements dictate solution of
    problems.
  • Internal needs of design e.g. quality specs.
    design theory.
  • Need for decreased uncertainty.

18
Categorization of Engineering Design Knowledge
  • Fundamental design concepts.
  • Criteria and specifications.
  • Theoretical tools.
  • Quantitative data.
  • Practical considerations.
  • Design instrumentalities.

19
Knowledge Generating Activities
  • Transfer from science.
  • Invention
  • Theoretical engineering research
  • Experimental engineering research
  • Design practice
  • Production
  • Direct trial

20
Evolutionary Model of Knowledge Growth
  • Variation-Selection
  • Consistent with GAs
  • Not as detailed in its mechanisms.
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