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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Sensor based fixture design and verification

Purushothaman, Radhakrishnan. January 2003 (has links)
Thesis (M.S.)--Worcester Polytechnic Institute. / Keywords: error proofing; foolproofing; poka-yoke; free-form surfaces; fixture. Includes bibliographical references (p. 76-78).
2

Computer-aided fixture design verification

Kang, Yuezhuang. January 2002 (has links)
Thesis (M.S.)--Worcester Polytechnic Institute. / Keywords: Fixture stiffness matrix; Jacobian matrix; kinetic model; geometric model; fixture design verification; stability analysis; tolerance analysis; tolerance assignment. Includes bibliographical references (p. 92-97).
3

Finite Element Analysis for Fixture Stiffness

Zheng, Yi. January 2005 (has links)
Dissertation (Ph.D.) -- Worcester Polytechnic Institute. / Keywords: Computer-aided fixture design; Finite element analysis; Fixture Stiffness. Includes bibliographical references (p. 140-148).
4

Finite Element Analysis for Fixture Stiffness

Zheng, Yi 05 May 2005 (has links)
With growing demands on improved product quality and shorter time to market, there is need for rigorous but practical tools to support the fixture design and analysis process. Computer-aided fixture design (CAFD), with predictable fixture stiffness, becomes a means to provide an appropriate solution in fixture design. The effectiveness of previous CAFD systems is not fully satisfactory partially because analysis of fixture stiffness has not kept pace with the development of CAFD. The dissertation research provides a model of fixture unit stiffness analysis and an experimental method of identifying contact stiffness parameters. The model and the method offer the potential for a more realistic analysis of fixture stiffness properties of a fixture-workpiece system, based on a fixture unit description. An FEA model of fixture unit stiffness is developed with contact elements for solving contact problems encountered in the study of fixture unit stiffness. The penalty function method is used to model the contact conditions in the energy equation of the general FEA and to describe the nonlinearity of connection shown in previous experiments. The contact and friction conditions are represented mathematically in the FEA model. The FEA model and the analysis procedure are validated by numerical simulation. An experimental study on contact parameters is carried out to identify contact stiffness, including normal contact stiffness and tangential contact stiffness, by both static and dynamic approaches. For normal contact stiffness, a static identification procedure is developed to estimate the contact parameters, using experimental data. Four factors - testing environment, contact area, surface finish of the specimen, and normal loads, - are examined to see how they affect the behavior of the contact interface. A dynamic method is also used to identify normal contact stiffness. A scheme of eigenvalue analysis is developed to test the contact structure to estimate contact stiffness. The dynamic test results are compared with the results of static test under the same experimental condition and a reliable correspondence is presented. Similar to methods devised to identify normal contact stiffness, a frequency-domain identification system is developed to estimate tangential contact stiffness, using FEA and experimental data. A simulation study on vibration data from tangential contact model is presented in this study. The experimental study is carried out and tangential contact stiffness is estimated based on numerical simulation and experimental data. This research establishes the finite element model of fixture unit stiffness and develops the experimental approaches to identify contact stiffness. Based on this study, the database of fixture stiffness can be built up, and further used in CAFD
5

Sensor Based Fixture Design and Verification

Purushothaman, Radhakrishnan 21 January 2003 (has links)
The objectives of Sensor Based Fixture Design and Verification (SFDV) research are to provide the means for detecting contact failure of the workpiece with fixture locators and for preventing incorrect loading of the workpiece in a fixture. The fixtures that involve complex free-form surfaces especially in the aerospace industries face problems caused by the contact failure of the workpiece with locators. In batch and mass production defects often occur due to incorrect loading of the workpiece in a fixture by an operator due to fatigue or inadvertence. The current fixturing research is focussed on improving the fixture quality and other aspects and do not address these issues. This research is focussed on three areas, to generate algorithms for automatically foolproofing the fixtures, to build locators with embedded sensors that could be used to verify the contact and foolproof the existing fixtures, and to design and experimentally validate fixtures for free-form surfaces with sensors to verify the location. In foolproofing, workpieces were classified into different categories to identify the existence of a solution and the geometry was simplified and used to search for a solution based on symmetry/asymmetry to discover a foolproofing location. The algorithms were implemented in a CAD software and the solutions were verified in 3D space. The locators with inbuilt sensors were designed for foolproofing and location verification purposes and the sensors were used in case studies to establish credibility. A sensor based fixture design method is created for the part location of free-form surfaces using fiber optic sensors. An experimental fixture with sensors incorporated in the locators was used to determine the effects of surface curvature on the sensitivity of the sensors. A new theory on best locations for the sensor based locators by utilizing surface curvature is proposed based on the experimental results. The SFDV implementation may help realize the dream for any manufacturing sys­tem aspiring to move beyond the six sigma levels of quality and achieve zero defects.
6

Computer-Aided Fixture Design Verification

Kang, Yuezhuang 08 January 2002 (has links)
This study presents Computer-Aided Fixture Design Verification (CAFDV) - the methods and implementations to define, measure and optimize the quality of fixture designs. CAFDV verifies a fixture for its locating performance, machining surface accuracy, stability, and surface accessibility. CAFDV also optimizes a fixture for its locator layout design, initial clamping forces, and tolerance specification. The demand for CAFDV came from both fixture design engineers and today's supply chain managers. They need such a tool to inform them the quality of a fixture design, and to find potential problems before it is actually manufactured. For supply chain managers, they will also be able to quantitatively measure and control the product quality from vendors, with even little fixture design knowledge. CAFDV uses two models - one geometric and one kinetic - to represent, verify and optimize fixture designs. The geometric model uses the Jacobian Matrix to establish the relationship between workpiece-fixture displacements, and the kinetic model uses the Fixture Stiffness Matrix to link external forces with fixture deformation and workpiece displacement. Computer software for CAFDV has also been developed and integrated with CAD package I-DEAS TM. CAD integration and a friendly graphic user interface allows the user to have easy interactions with 3D models and visual feedback from analysis results.

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