Chapter 9, 10, 11 - Ivy Tech -
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Transcript Chapter 9, 10, 11 - Ivy Tech -
Product Architecture, Industrial
Design, Design for Manufacturing
Chapter 9: Product Architecture
Product Architecture has 2 elements:
Functional – individual operations and transformations
that contribute to the overall performance of the
product
Physical – parts, components, and subassemblies that
implement the product function
Creating modules or building blocks can help in
organization and manufacturing
Implications of the Architecture
Decisions of architecture can affect many issues:
Product change
Upgrades, Add-ons, Adaptation, Wear, Consumption,
Flexibility in use, Reuse
Product variety
Component standardization
Product performance
Manufacturability
Product development management
Examples
Exhibit 9-4 pg 169 – Swatch watch
Example – F-150
Example – Sport Trac
Establishing Architecture Steps
1.
Create a schematic of the product
Layout of the components, their hierarchy and interactions
2. Cluster the elements of the schematic
Group the components into clusters based on:
Geometric integration and precision
Function sharing
Capabilities of vendors
Similarity of design or production technology
Localization of change
Accommodating variety
Enabling standardization
Portability of the interfaces
Establishing Architecture Steps
3. Create the rough geometry
Create a rough, basic 3-D and 2-D sketches
4. Identify the fundamental and incidental interactions
Likely the functional groups or clusters will be
assigned to the respective areas of expertise for further
design. As a cross functional team the interaction
between groups should be know
Fundamental interactions – interactions of components
based on function of the product
Incidental interactions – interactions that arise from
physical arangement
Delayed Differentiation
On occasion variations in architecture will be delayed
until further in the Supply Chain.
Examples – voltage components, product variation or
customer ordering
Design evolves around the customized group to allow
for the options
Chapter 11: Design for
Manufacturing
Detail design decisions have a substantial impact on
final product quality and cost
Development teams face multiple and often
conflicting goals
Important to have metrics to compare alternative
designs
Dramatic improvements often require substantial
creative efforts early in the process
Well-defined method makes the decision-making
process much easier
DFM
Requires a cross-functional team, internal to the
organization and external experts, as well as vendors
Performed throughout the process
Overview:
1.
2.
3.
4.
5.
Estimate the manufacturing costs
Reduce the costs of components
Reduce the costs of assembly
Reduce the cost of supporting production
Consider the impact of DFM decision on other facors
Estimate the Manufacturing $
Manufacturing $ = ∑Input costs
Raw material
Purchased components
Employees effort
Energy
Equipment
Component $
Assembly $
Overhead $
Estimating the Manufacturing $
Fixed $ vs. Variable $
Fixed - $ spent regardless of the quantity of products
sold
Variable - $ spent that changes based on the quantity of
products sold
Estimate the $ of standard components
Estimate the $ of custom components
Estimate the $ of assembly
Estimate the $ of overhead cost
Reduce the $ of Components
Understand the process constraints and cost drivers
Redesign components to eliminate processing steps
Choose an appropriate Economic scale
Standardize components and processes
Reduce the $ of Assembly - DFA
Integrate parts
Maximize ease of assembly
Parts inserted from the top of the assy
Part is self-aligning
Part does not need to be oriented
Part requires only one hand for assy
Part requires no tools
Part is assembled in a single, linear motion
Part is secured imediately upon insertion
Reduce the $ of Supporting
Production
Minimize systemic complexity
Error proofing
Consider the impact of DFM
The impact of DFM on development time
The impact of DFM on development cost
The impact of DFM on product quality
The impact of DFM on external factors
Component reuse
Life cycle cost