Product Design Process
siisiir
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15 slides
May 09, 2018
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About This Presentation
Product design process
Slide Content
Pr obl em Sol vi ng Met hodol ogy
The Product
Design
Process
The Product
Design
Process
Everything is designed
Few things are designed well
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Few things are designed well
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“
The Four C’s of
Design
Creativity
•Requires creation of something that has not existed before or not existed in the
designer’s mind before
Complexity
•Requires decisions on many variables and parameters
Choice
•Requires making choices between many possible solutions at all levels, from basic
concepts to smallest detail of shapes
Compromise
•Requires balancing multiple and sometimes conflicting requirements
Design
Creativity
•Requires creation of something that has not existed before or not existed in the
designer’s mind before
Complexity
•Requires decisions on many variables and parameters
Choice
•Requires making choices between many possible solutions at all levels, from basic
concepts to smallest detail of shapes
Compromise
•Requires balancing multiple and sometimes conflicting requirements
What is
Design?
•Difference between Design and Discovery:
Discovery is getting the first sight of something but design is the product of
planning and work
•Good design requires both analysis and synthesis
(Analysis is to breakdown complex problems to manageable parts and synthesis
involves the identification of the design elements that will compromise the
product and the combination of the part solutions into a total workable system)
Desi gn est abl i shes and def i nes sol ut i ons t o and per t i nent
st r uct ur es f or pr obl ems not sol ved bef or e, or new sol ut i ons t o
pr obl ems whi ch have pr evi ousl y been sol ved i n a di f f er ent way
Design?
•Difference between Design and Discovery:
Discovery is getting the first sight of something but design is the product of
planning and work
•Good design requires both analysis and synthesis
(Analysis is to breakdown complex problems to manageable parts and synthesis
involves the identification of the design elements that will compromise the
product and the combination of the part solutions into a total workable system)
Desi gn est abl i shes and def i nes sol ut i ons t o and per t i nent
st r uct ur es f or pr obl ems not sol ved bef or e, or new sol ut i ons t o
pr obl ems whi ch have pr evi ousl y been sol ved i n a di f f er ent way
The Desi gn Process-
A Si mpl i fi ed Approach
General information
Design Operation OutcomeSpecific
information
Evaluation
yes
NO
Feedback loop
Go to the next step
A Si mpl i fi ed Approach
General information
Design Operation OutcomeSpecific
information
Evaluation
yes
NO
Feedback loop
Go to the next step
Sci enti fi c Method vs
Desi gn Method
Existing knowledge State of the art
Scientific curiosity
Hypothesis
Logical analysis
Proof
Identification of need
Conceptualization
Feasibility analysis
Production
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Scientific Method Design Method
Desi gn Method
Existing knowledge State of the art
Scientific curiosity
Hypothesis
Logical analysis
Proof
Identification of need
Conceptualization
Feasibility analysis
Production
C
o
m
m
u
n
i
c
a
t
i
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n
A
c
c
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p
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Scientific Method Design Method
Consideration of Good Design
•Design Requirements
•Functional performance (F, σ, power, deflection)
•Complementary performance (life of design, robustness,
reliability, ease, economy, safety of maintenance)
•Total Life Cycle
Material selection, productivity, durability
•Regulatory and Social Issues
ASTM, ASME standards, codes of ethics, EPA
requirements
•Design Requirements
•Functional performance (F, σ, power, deflection)
•Complementary performance (life of design, robustness,
reliability, ease, economy, safety of maintenance)
•Total Life Cycle
Material selection, productivity, durability
•Regulatory and Social Issues
ASTM, ASME standards, codes of ethics, EPA
requirements
Design Process
•I. Conceptual Design
•II. Embodiment Design
•III. Detail Design
•IV. Planning for Manufacture
•V. Planning for Distribution
•VI. Planning for use
•VII. Planning for Retirement of the Product
•I. Conceptual Design
•II. Embodiment Design
•III. Detail Design
•IV. Planning for Manufacture
•V. Planning for Distribution
•VI. Planning for use
•VII. Planning for Retirement of the Product
I. Conceptual Design
•Identification of customer needs
•Problem definition
•Gathering information
•Conceptualization
•Concept selection
•Refinement of product design specification
•Design review
•Identification of customer needs
•Problem definition
•Gathering information
•Conceptualization
•Concept selection
•Refinement of product design specification
•Design review
II. Embodiment Design
•Product architecture
•Configuration design of parts and components (feature present like
holes, ribs, splines, and curves are configured). Modeling and simulation may be
performed. The generation of physical model of the part with rapid prototyping
processes may be appropriate)
•Parametric design of parts and components (exact dimensions and
tolerances, materials and processes, robustness)
•Product architecture
•Configuration design of parts and components (feature present like
holes, ribs, splines, and curves are configured). Modeling and simulation may be
performed. The generation of physical model of the part with rapid prototyping
processes may be appropriate)
•Parametric design of parts and components (exact dimensions and
tolerances, materials and processes, robustness)
III. Detail Design
•In this phase the design is brought to the stage of a complete
engineering description of a tested and producible product.
•In this phase the design is brought to the stage of a complete
engineering description of a tested and producible product.
IV. Planning for Manufacture
•Designing specialized tools and fixtures
•Specifying the production plant that will be used
•Planning the work schedules and inventory controls
•Planning the quality assurance systems
•Establishing the standard time and labor costs for
each operation
•Establishing the system of information flow
necessary to control the manufacturing operation
•Designing specialized tools and fixtures
•Specifying the production plant that will be used
•Planning the work schedules and inventory controls
•Planning the quality assurance systems
•Establishing the standard time and labor costs for
each operation
•Establishing the system of information flow
necessary to control the manufacturing operation
V. Planning for Distribution
•Shelf life consideration
•System of warehouses for distribution of the product needs to be
designed
•Marketing efforts on advertising and news media techniques must be
selected
•For technical activities specialized sale brochures and performance
test data must be generated.
•Shelf life consideration
•System of warehouses for distribution of the product needs to be
designed
•Marketing efforts on advertising and news media techniques must be
selected
•For technical activities specialized sale brochures and performance
test data must be generated.
VI. Planning for use
•Ease of maintenance, reliability, product safety,
convenience in use (human factors engineering),
aesthetic appeal, economy of operation, and
duration of service are some of the questions to be
answered in a consumer oriented product.
•Acquisition of reliable data on failure, service lives,
and consumer complaint and attitudes to provide a
basis for product improvement in the next design is
an important phase VI activity.
•Ease of maintenance, reliability, product safety,
convenience in use (human factors engineering),
aesthetic appeal, economy of operation, and
duration of service are some of the questions to be
answered in a consumer oriented product.
•Acquisition of reliable data on failure, service lives,
and consumer complaint and attitudes to provide a
basis for product improvement in the next design is
an important phase VI activity.
VII. Planning for Retirement
of the Product
•The final step in the design process is the disposal of the product when it
has reached the end of its useful life.
•Useful life may be determined by actual deterioration and wear or it
may be determined by technological obsolescence.
•Industrial ecology considerations dictate a plan for either disposal of the
product in an environmentally safe way or, better, the recycling of its
materials, or remanufacture or reuse of product components.
of the Product
•The final step in the design process is the disposal of the product when it
has reached the end of its useful life.
•Useful life may be determined by actual deterioration and wear or it
may be determined by technological obsolescence.
•Industrial ecology considerations dictate a plan for either disposal of the
product in an environmentally safe way or, better, the recycling of its
materials, or remanufacture or reuse of product components.
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