F Villeneuve
John Wiley & Sons
e druk, 2010
9781848211186
Geometric Tolerancing of Products
Specificaties
Gebonden, 394 blz.
|
Engels
John Wiley & Sons |
e druk, 2010
ISBN13: 9781848211186
Rubricering
Onderdeel van serie
ISTE
Verwachte levertijd ongeveer 16 werkdagen
Samenvatting
This title describes the various research results in the field of geometric tolerancing of products, an activity that highlights the difficult scientific locks. The collection is of great importance for further innovation in the development of industrial products.
Specificaties
ISBN13:9781848211186
Taal:Engels
Bindwijze:gebonden
Aantal pagina's:394
Uitgever:John Wiley & Sons
Serie:ISTE
Inhoudsopgave
<p>PART I. GEOMETRIC TOLERANCING ISSUES 1<br /> <br /> Chapter 1. Current and Future Issues in Tolerancing: the GD&T French Research Group (TRG) Contribution 3<br /> Luc MATHIEU and François VILLENEUVE</p>
<p>1.1. Introduction 3</p>
<p>1.2. Presentation of the Tolerancing Resarch Group: objectives and function 4</p>
<p>1.3. Synthesis of the approach and contributions of the group 5</p>
<p>1.4. Research perspectives 13</p>
<p>1.5. Media examples: centering and connecting rod–crank 15</p>
<p>1.6. Conclusion 17</p>
<p>1.7. Bibliography 19</p>
<p>PART II. GEOMETRIC TOLERANCING LANGUAGES 21</p>
<p>Chapter 2. Language of Tolerancing: GeoSpelling 23<br /> Alex BALLU, Jean–Yves DANTAN and Luc MATHIEU</p>
<p>2.1. Introduction 23</p>
<p>2.2. Concept of the GeoSpelling language 24</p>
<p>2.3. Geometric features 26</p>
<p>2.4. Characteristic 29</p>
<p>2.5. Operations 38</p>
<p>2.6. Conditions 43</p>
<p>2.7. Specifications on assemblies quantifiers 44</p>
<p>2.8. Applications to part specification 45</p>
<p>2.9. Applications to product specifications 48</p>
<p>2.10. Conclusion 51</p>
<p>2.11. Bibliography 52</p>
<p>Chapter 3. Product Model for Tolerancing 55<br /> Denis TEISSANDIER and Jérôme DUFAURE</p>
<p>3.1. Introduction 55</p>
<p>3.2. Objectives and stakes 56</p>
<p>3.3. Proposal for a product model 58</p>
<p>3.4. Benefits of the IPPOP product model 68</p>
<p>3.5. Application on the centering device 73</p>
<p>3.6. Conclusion 84</p>
<p>3.7. Bibliography 84</p>
<p>Chapter 4. Representation of Mechanical Assemblies and Specifications by Graphs 87<br /> Alex BALLU, Luc MATHIEU and Olivier LEGOFF</p>
<p>4.1. Introduction 87</p>
<p>4.2. Components and joints 89</p>
<p>4.3. The requirements, technical conditions and specifications 97</p>
<p>4.4. Manufacturing set–ups 100</p>
<p>4.5. Displacements between situation features and associated loops103</p>
<p>4.6. The key elements 107</p>
<p>4.7. Conclusion 109</p>
<p>4.8. Bibliography 110</p>
<p>Chapter 5. Correspondence between Data Handled by the Graphs and Data Product 111<br /> Denis TEISSANDIER and Jérôme DUFAURE</p>
<p>5.1. Introduction 111</p>
<p>5.2. Correspondence between tolerancing graphs and the product data 112</p>
<p>5.3. Correspondence between manufacturing set–ups and the data product 118</p>
<p>5.4. Conclusion 121</p>
<p>PART III. 3D TOLERANCE STACK–UP 123</p>
<p>Chapter 6. Writing the 3D Chain of Dimensions (Tolerance Stack–Up) in Symbolic Expressions 125<br /> Pierre BOURDET, François THIÉBAUT and Grégory CID</p>
<p>6.1. Introduction 125</p>
<p>6.2. A reminder of the establishment of the unidirectional chain of dimensions by the l method 126</p>
<p>6.3. Establishment in writing of a chain of dimensions in 3D by the method of indeterminates in the case of a rigid body 135</p>
<p>6.4. Consideration of the contact between parts in the mechanisms 142</p>
<p>6.5. Mechanisms composed of flexible parts, joints without gap (or imposed contact) and imposed effort 144</p>
<p>6.6. Conclusion 147</p>
<p>6.7. Bibliography 148</p>
<p>Chapter 7. Tolerance Analysis and Synthesis, Method of Domains 151<br /> Max GIORDANO, Eric PAIREL and Serge SAMPER</p>
<p>7.1. Introduction 151</p>
<p>7.2. Deviation torsor and joint torsor 152</p>
<p>7.3. Equations of loops 155</p>
<p>7.4. Deviation and clearance domains 158</p>
<p>7.5. Representation and properties of the domains 162</p>
<p>7.6. Application to the analysis of simple chains 168</p>
<p>7.7. Case of assemblies with parallel joints 173</p>
<p>7.8. Taking elastic displacements into account 176</p>
<p>7.9. Conclusion 180</p>
<p>7.10. Bibliography 180</p>
<p>Chapter 8. Parametric Specification of Mechanisms 183<br /> Philippe SERRÉ, Alain RIVIÈRE and André CLÉMENT</p>
<p>8.1. Introduction 183</p>
<p>8.2. Problem of the parametric specification of complete and consistent dimensioning 184</p>
<p>8.3. Generation of parametric tolerancing by the differential variation of the specification of dimensioning 188</p>
<p>8.4. Problem of the specification transfer 192</p>
<p>8.5. Expression of parametric tolerancing 193</p>
<p>8.6. Case study 198</p>
<p>8.7. Conclusion 204</p>
<p>8.8. Bibliography 205</p>
<p>PART IV. METHODS AND TOOLS 207</p>
<p>Chapter 9. CLIC: A Method for Geometrical Specification of Products 209<br /> Bernard ANSELMETTI</p>
<p>9.1. Introduction 209</p>
<p>9.2. Input of a tolerancing problem 210</p>
<p>9.3. Part positioning 212</p>
<p>9.4. Tolerancing of positioning surfaces 217</p>
<p>9.5. Generation of functional requirements 221</p>
<p>9.6. Specification synthesis 222</p>
<p>9.7. Tolerance chain result 227</p>
<p>9.8. Tolerance synthesis 234</p>
<p>9.9. Conclusion 238</p>
<p>9.10. Bibliography 238</p>
<p>Chapter 10. MECAmaster: a Tool for Assembly Simulation from Early Design, Industrial Approach 241<br /> Paul CLOZEL and Pierre–Alain RANCE</p>
<p>10.1. Introduction 241</p>
<p>10.2. General principle, 3D tolerance calculation 242</p>
<p>10.3. Application to assembly calculation 245</p>
<p>10.4. From model to parts tolerancing 263</p>
<p>10.5. Statistical tolerancing 268</p>
<p>10.6. Industrial examples 269</p>
<p>10.7. Conclusion 271</p>
<p>10.8. Bibliography 272</p>
<p>PART V. MANUFACTURING TOLERANCING 275</p>
<p>Chapter 11. Geometric Manufacturing Simulation 277<br /> Stéphane TICHADOU and Olivier LEGOFF</p>
<p>11.1. Introduction 277</p>
<p>11.2. Modeling of manufacturing set–up 279</p>
<p>11.3. Approaches to geometric manufacturing simulation 288</p>
<p>11.4. Conclusion 303</p>
<p>11.5. Bibliography 303</p>
<p>Chapter 12. 3D Analysis and Synthesis of Manufacturing Tolerances 305<br /> Frédéric VIGNAT and François VILLENEUVE</p>
<p>12.1. Introduction 305</p>
<p>12.2. Manufacturing transfer, analysis and synthesis in 1D 306</p>
<p>12.3. 3D manufacturing simulation model (MMP) 314</p>
<p>12.4. From the manufacturing process to the MMP 317</p>
<p>12.5. 3D analysis of the functional tolerances 323</p>
<p>12.6. 3D synthesis of manufacturing tolerances 329</p>
<p>12.7. Conclusion 338</p>
<p>12.8. Bibliography 339</p>
<p>PART VI. UNCERTAINTIES AND METROLOGY 341</p>
<p>Chapter 13. Uncertainties in Tolerance Analysis and Specification Checking 343<br /> Jean–Marc LINARES and Jean Michel SPRAUEL</p>
<p>13.1. Introduction 343</p>
<p>13.2. Proposal for a statistical model of real surfaces 343</p>
<p>13.3. Applications in metrology 354</p>
<p>13.4. Application to tolerance analysis 367</p>
<p>13.5. Conclusion 373</p>
<p>13.6. Bibliography 374</p>
<p>List of Authors 375</p>
<p>Index 377</p>
<p>1.1. Introduction 3</p>
<p>1.2. Presentation of the Tolerancing Resarch Group: objectives and function 4</p>
<p>1.3. Synthesis of the approach and contributions of the group 5</p>
<p>1.4. Research perspectives 13</p>
<p>1.5. Media examples: centering and connecting rod–crank 15</p>
<p>1.6. Conclusion 17</p>
<p>1.7. Bibliography 19</p>
<p>PART II. GEOMETRIC TOLERANCING LANGUAGES 21</p>
<p>Chapter 2. Language of Tolerancing: GeoSpelling 23<br /> Alex BALLU, Jean–Yves DANTAN and Luc MATHIEU</p>
<p>2.1. Introduction 23</p>
<p>2.2. Concept of the GeoSpelling language 24</p>
<p>2.3. Geometric features 26</p>
<p>2.4. Characteristic 29</p>
<p>2.5. Operations 38</p>
<p>2.6. Conditions 43</p>
<p>2.7. Specifications on assemblies quantifiers 44</p>
<p>2.8. Applications to part specification 45</p>
<p>2.9. Applications to product specifications 48</p>
<p>2.10. Conclusion 51</p>
<p>2.11. Bibliography 52</p>
<p>Chapter 3. Product Model for Tolerancing 55<br /> Denis TEISSANDIER and Jérôme DUFAURE</p>
<p>3.1. Introduction 55</p>
<p>3.2. Objectives and stakes 56</p>
<p>3.3. Proposal for a product model 58</p>
<p>3.4. Benefits of the IPPOP product model 68</p>
<p>3.5. Application on the centering device 73</p>
<p>3.6. Conclusion 84</p>
<p>3.7. Bibliography 84</p>
<p>Chapter 4. Representation of Mechanical Assemblies and Specifications by Graphs 87<br /> Alex BALLU, Luc MATHIEU and Olivier LEGOFF</p>
<p>4.1. Introduction 87</p>
<p>4.2. Components and joints 89</p>
<p>4.3. The requirements, technical conditions and specifications 97</p>
<p>4.4. Manufacturing set–ups 100</p>
<p>4.5. Displacements between situation features and associated loops103</p>
<p>4.6. The key elements 107</p>
<p>4.7. Conclusion 109</p>
<p>4.8. Bibliography 110</p>
<p>Chapter 5. Correspondence between Data Handled by the Graphs and Data Product 111<br /> Denis TEISSANDIER and Jérôme DUFAURE</p>
<p>5.1. Introduction 111</p>
<p>5.2. Correspondence between tolerancing graphs and the product data 112</p>
<p>5.3. Correspondence between manufacturing set–ups and the data product 118</p>
<p>5.4. Conclusion 121</p>
<p>PART III. 3D TOLERANCE STACK–UP 123</p>
<p>Chapter 6. Writing the 3D Chain of Dimensions (Tolerance Stack–Up) in Symbolic Expressions 125<br /> Pierre BOURDET, François THIÉBAUT and Grégory CID</p>
<p>6.1. Introduction 125</p>
<p>6.2. A reminder of the establishment of the unidirectional chain of dimensions by the l method 126</p>
<p>6.3. Establishment in writing of a chain of dimensions in 3D by the method of indeterminates in the case of a rigid body 135</p>
<p>6.4. Consideration of the contact between parts in the mechanisms 142</p>
<p>6.5. Mechanisms composed of flexible parts, joints without gap (or imposed contact) and imposed effort 144</p>
<p>6.6. Conclusion 147</p>
<p>6.7. Bibliography 148</p>
<p>Chapter 7. Tolerance Analysis and Synthesis, Method of Domains 151<br /> Max GIORDANO, Eric PAIREL and Serge SAMPER</p>
<p>7.1. Introduction 151</p>
<p>7.2. Deviation torsor and joint torsor 152</p>
<p>7.3. Equations of loops 155</p>
<p>7.4. Deviation and clearance domains 158</p>
<p>7.5. Representation and properties of the domains 162</p>
<p>7.6. Application to the analysis of simple chains 168</p>
<p>7.7. Case of assemblies with parallel joints 173</p>
<p>7.8. Taking elastic displacements into account 176</p>
<p>7.9. Conclusion 180</p>
<p>7.10. Bibliography 180</p>
<p>Chapter 8. Parametric Specification of Mechanisms 183<br /> Philippe SERRÉ, Alain RIVIÈRE and André CLÉMENT</p>
<p>8.1. Introduction 183</p>
<p>8.2. Problem of the parametric specification of complete and consistent dimensioning 184</p>
<p>8.3. Generation of parametric tolerancing by the differential variation of the specification of dimensioning 188</p>
<p>8.4. Problem of the specification transfer 192</p>
<p>8.5. Expression of parametric tolerancing 193</p>
<p>8.6. Case study 198</p>
<p>8.7. Conclusion 204</p>
<p>8.8. Bibliography 205</p>
<p>PART IV. METHODS AND TOOLS 207</p>
<p>Chapter 9. CLIC: A Method for Geometrical Specification of Products 209<br /> Bernard ANSELMETTI</p>
<p>9.1. Introduction 209</p>
<p>9.2. Input of a tolerancing problem 210</p>
<p>9.3. Part positioning 212</p>
<p>9.4. Tolerancing of positioning surfaces 217</p>
<p>9.5. Generation of functional requirements 221</p>
<p>9.6. Specification synthesis 222</p>
<p>9.7. Tolerance chain result 227</p>
<p>9.8. Tolerance synthesis 234</p>
<p>9.9. Conclusion 238</p>
<p>9.10. Bibliography 238</p>
<p>Chapter 10. MECAmaster: a Tool for Assembly Simulation from Early Design, Industrial Approach 241<br /> Paul CLOZEL and Pierre–Alain RANCE</p>
<p>10.1. Introduction 241</p>
<p>10.2. General principle, 3D tolerance calculation 242</p>
<p>10.3. Application to assembly calculation 245</p>
<p>10.4. From model to parts tolerancing 263</p>
<p>10.5. Statistical tolerancing 268</p>
<p>10.6. Industrial examples 269</p>
<p>10.7. Conclusion 271</p>
<p>10.8. Bibliography 272</p>
<p>PART V. MANUFACTURING TOLERANCING 275</p>
<p>Chapter 11. Geometric Manufacturing Simulation 277<br /> Stéphane TICHADOU and Olivier LEGOFF</p>
<p>11.1. Introduction 277</p>
<p>11.2. Modeling of manufacturing set–up 279</p>
<p>11.3. Approaches to geometric manufacturing simulation 288</p>
<p>11.4. Conclusion 303</p>
<p>11.5. Bibliography 303</p>
<p>Chapter 12. 3D Analysis and Synthesis of Manufacturing Tolerances 305<br /> Frédéric VIGNAT and François VILLENEUVE</p>
<p>12.1. Introduction 305</p>
<p>12.2. Manufacturing transfer, analysis and synthesis in 1D 306</p>
<p>12.3. 3D manufacturing simulation model (MMP) 314</p>
<p>12.4. From the manufacturing process to the MMP 317</p>
<p>12.5. 3D analysis of the functional tolerances 323</p>
<p>12.6. 3D synthesis of manufacturing tolerances 329</p>
<p>12.7. Conclusion 338</p>
<p>12.8. Bibliography 339</p>
<p>PART VI. UNCERTAINTIES AND METROLOGY 341</p>
<p>Chapter 13. Uncertainties in Tolerance Analysis and Specification Checking 343<br /> Jean–Marc LINARES and Jean Michel SPRAUEL</p>
<p>13.1. Introduction 343</p>
<p>13.2. Proposal for a statistical model of real surfaces 343</p>
<p>13.3. Applications in metrology 354</p>
<p>13.4. Application to tolerance analysis 367</p>
<p>13.5. Conclusion 373</p>
<p>13.6. Bibliography 374</p>
<p>List of Authors 375</p>
<p>Index 377</p>