Product Design for ModularityThe current marketplace is undergoing an accelerated pace of change that challenges corporations to innovate new techniques to respond rapidly to an ever-changing environment. At the center of this changing environment is a new generation of empowered buyers (customers) equipped with fast evolving technologies that allow them to buy from markets scattered across the globe. Empowering the customers has deprived organizations of what was once their right-to introduce new products slowly, at their own leisure. Organizations used to introduce new products every few years, and, for the most part, products offered limited functionalities and features. A low-priced quality product-irrespective of customer satisfaction-was a guaranteed ticket for success. New global economies and global markets changed business practices and focused on the customer as the major player in the economy. Organizations now fail or succeed based upon their ability to respond quickly to changing customer demands and to utilize new technological innovations. In such an environment, the advantage goes to the firm that can offer greater varieties of new products with higher performance and greater overall appeal. In order to compete in this fast-paced global market, organizations need to produce products that can be easily configured to offer distinctive capabilities compared to the competition. Furthermore, organizations need to develop new methods and techniques to react rapidly to required changes in products and market trends and to shorten the product development cycle, which will enable them to gain more economic competitiveness. |
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Page 59
... Relationship Matrix between WHATS and HOWS The quality function deployment team now fills the inside of the house of quality ( the relationship ... relationship △ represents a weak relationship The box is left blank Design for Modularity 59.
... Relationship Matrix between WHATS and HOWS The quality function deployment team now fills the inside of the house of quality ( the relationship ... relationship △ represents a weak relationship The box is left blank Design for Modularity 59.
Page 60
... relationship O represents a positive relationship △ represents a negative relationship A represents a strong negative relationship The correlation matrix identifies which product features support one another and which are in conflict ...
... relationship O represents a positive relationship △ represents a negative relationship A represents a strong negative relationship The correlation matrix identifies which product features support one another and which are in conflict ...
Page 70
... relationships between components , 1 if the relationship exists and 0 otherwise . This binary relationship between components is arranged in a vector form , the system - level specifications vector ( SLSV ) . Figure 3.10 illustrates the ...
... relationships between components , 1 if the relationship exists and 0 otherwise . This binary relationship between components is arranged in a vector form , the system - level specifications vector ( SLSV ) . Figure 3.10 illustrates the ...
Contents
Product Development Process An Introduction | 1 |
Modular Design | 19 |
Design for Modularity | 49 |
Copyright | |
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adjustment or replacement algorithm analyzed assembly associated Attribute automation basic Bearing CALLED SUBTREES 11 cellular manufacturing clustering coefficients columns components concept constraints Crankshaft cross-functional team cu.mm customer needs customer requirements decomposition design and manufacturing Design for Assembly Design for Manufacture Design for Modularity design process DFMA diameter END SUBTREE essential Yes families Figure fixtures fog lamp Functional Objectives Functionality Analysis GD&T Gear Group Technology house of quality identified illustrates impact implemented incidence matrix input insertion integrated investment cost length of cut machine type main journal main shoulder manufacturing processes Manufacturing Systems Material removal volume method methodology metric modular design modular products modules number of machines output overall function parameters performed phase physical plql problem Process Planning product design product development product features quality function deployment radius Robot selected sequence Shaft Similarity Matrix Step structure System-Level Specifications Table techniques tool type