1996 Table of Contents

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1996 Table of Contents

1. Optimizing of selective laser sintering method
2. Fabrication of powder products with variable cross sections using the method of laser layer-by-layer selective sintering
3. Exploratory investigation of layered fabrication applied to construction automation
4. Adaptive slicing of parametrizable algebraic surfaces for Layered Manufacturing
5. Thermal design of material quality in rapid prototyping techniques
6. Infrared feedback-based control of the temperature distribution in thermal rapid prototyping
7. Proceedings of the 1996 ASME International Mechanical Engineering Congress and Exposition
8. Propagating topological tolerances for rapid prototyping
9. Thermal simulation and model-based adaptive control of plasma-arc processing on metal plates
10. Issues in computer modeling and interfaces to solid freeform fabrication
11. Fiber coupled high power laser diodes for solid freeform fabrication directly from metal powders
12. Rapid response manufacturing in distributed environments: the important roles of process planning and open architectures
13. Adaptive regulation of thermal desktop manufacturing methods
14. Solid freeform fabrication: an overview
15. Proceedings of the 1996 ASME International Mechanical Engineering Congress and Exposition
16. Cost reduction by rapid prototyping photoelasticity
17. Stereolithography method for the rapid manufacture of glass-fiber-reinforced composites
18. Design and manufacturing of composite fiber semidisplacement hull powered by solar energy
19. New CAD tool for rapid prototyping
20. European effort refines medical prototyping
21. Thermomechanical modeling of molten metal droplet solidification applied to layered manufacturing
22. Modelling for all occasions
23. Integration of MRI and stereolithography to build medical models: A case study
24. Predicting total build-time and the resultant cure depth of the 3D stereolithography process
25. Adaptive slicing using stepwise uniform refinement
26. Structural quality of parts processed by fused deposition
27. Study of stereolithography file errors and repair. Part 2. Special cases
28. Study of stereolithography file errors and repair. Part 1. Generic solution
29. How close are moulded parts from RT moulds to series production?
30. Interfacial fracture testing of deposited metal layers under four-point bending
31. Patterning for planar waveguides
32. Overview of thermal spray processes
33. Polycaprolactone internal plasticization of stereolithography resins for improving impact toughness
34. Novel selective-area gripper for layered assembly of laminated objects
35. Post-cure shrinkage of photo-sensitive material used in laser lithography process
36. Octree reinforced thin-shell rapid prototyping
37. Design of a new singularity-free robotic wrist
38. Droplet-level modeling of thermal stresses in layered manufacturing methods
39. New slant in rapid prototyping
40. Determining fabrication orientations for rapid prototyping with stereolithography apparatus
41. Solid modeling systems
42. CAD model slicing and surface smoothing for building rapid prototyping parts
43. Process modeling for fused deposition of ceramics
44. Addressing today's technology with new methods
45. CASTTOOL prototyping for injection molding, where is it going?
46. Practical comparison of rapid prototyping and tooling options
47. Rover's rapid response
48. FDC, rapid fabrication of structural components
49. Mechanisms of carbon dioxide laser stereolithography
50. Automated laser scanning based on orthogonal cross sections
51. Geometrically structured acrylic resin and titanium implants in hard tissue
52. Solid ideas
53. Conceptual framework for the thermal process modelling of fused deposition
54. Correlation between the mechanical properties and the homogeneity of some photopolymerized acrylic/methacrylic networks
55. Freeform fabrication of ceramics via stereolithography
56. Investigation into the rapid prototyping of moulds for expanded polystyrene foam
57. Computational methods for rapid prototyping of analytic solid models
58. Thermal model of polymer degradation during selective laser sintering of polymer coated ceramic powders
59. Viscosity analysis of photopolymer and glass-fibre composites for rapid layered manufacturing
60. Rapid mould-making system: Material properties and design considerations
61. Optimal pole adaptation and control in thermal rapid prototyping applications
62. Diode lasers point to desktop manufacturing
63. Enhanced resolution of stereolithography
64. Rapid prototyping applications for manufacturing
65. Intelligent rapid prototyping with fused deposition modelling
66. Importing and reshaping digitized data for use in rapid prototyping: A system for sculpting polygonal mesh surfaces
67. Using rapid prototyping to produce electrical discharge machining electrodes
68. Integration of technologist's and designer's activities in introducing computer-aided design and manufacture of cast products
69. Rapid prototyping developments
70. Construction of a surface model and layered manufacturing data from 3D homogenization output
71. Mechanisms of carbon dioxide laser stereolithography in epoxy-based materials
72. Rapid prototyping laboratory at RIT
73. Televised advanced manufacturing courses
74. Proceedings of the 1995 51st Annual Forum. Part 2 (of 3)
75. Stereolithography - a tool for rapid castings
76. Investigation of the effect of various build methods on the performance of rapid prototyping (stereolithography)
77. Issues in fabricating manufacturing tooling using powder-based additive freeform fabrication
78. Speeding product design through rapid prototyping
79. Fabrication of polymers and composites containing embedded sensors
80. Fabricating three-dimensional parts with photohardening method and its testing
81. Prototyping programs speed product design
82. Hypervapotron flow testing with rapid prototype models
83. Thermal issues in microcasting shape deposition manufacturing
84. Deposition strategies for control of microstructure, microporosity and surface roughness in droplet-based solid freeform fabrication of structural materials
85. Casting riser design optimization using genetic algorithms
86. Selective laser sintering of polycarbonate
87. Go fast to market with rapid prototyping
88. Proceedings of the 1995 27th International SAMPE Technical Conference
89. Enhanced stereolithography patterns for investment casting and rapid tooling
90. Stereolithography of ceramics
91. Energy delivery for selective laser sintering: issues and directions- a review
92. Materials for selective laser sintering processing
93. Rapid prototyping applications for manufacturing
94. Fastcast: integration and application of rapid prototyping and computational simulation to investment casting
95. Affordable, rapid composite tooling via laminated object manufacturing
96. Rapid prototyping of functional ceramic composites
97. Rapid prototyping materials rheology
98. Smart materials systems through mesoscale patterning
99. Rapid prototyping update
100. Highlights of the workshop on rapid prototyping in Japan and Europe
101. Rapid prototyping of structural ceramic components using selective laser sintering
102. Role of rapid prototyping in preoperative planning and patient-specific implant generation
103. Stereolithography and the biomedical engineering
104. New dimension for office printers
105. Rapid concept modelers
106. Computer-aided manufacturing of laminated engineering materials
107. Design for manufacturing using rapid prototypes
108. Proceedings of the 1995 International Conference & Exposition on Powder Metallurgy & Particulate Materials. Part 3 (of 3)
109. Manufacture of iron-copper composite parts using selective laser sintering (SLSTM)
110. Rapid prototyping for die casting: today's applications and future developments
111. Rapid prototyping - fact or fiction?
112. Laser systems for laminated objects manufacturing
113. Rapid objects manufacturing from liquid photosensitive compounds induced by pulsed and cw laser beams
114. Longer lifetimes revive water-cooled ion lasers
115. Review of rapid prototyping technologies and systems
116. Rapid prototyping: a young technology evolves
117. Rapid prototyping a model for business
118. Overview of research in the fields of laser surface modification and laser machining at the Integrated Manufacturing Technologies Institute, NRC
119. Spare parts for the over 50 crowd
120. New enabling technology for concurrent engineering: rapid prototyping and manufacturing (RPM)
121. Rapid prototyping
122. 3D visualization and morphosynthesis using volume slicing
123. Breaking the mould on prototyping.
124. A novel selective-area gripper for layered assembly of laminated objects.
125. Faster, bigger desktop modeler (Sanders ModelMaker II).
126. CyberCut: a World Wide Web based design-to-fabrication tool.
127. Forward thinkers take to reverse engineering.
128. Mold-filling software now accepts rapid-prototyping data format.
129. Who's who in service bureaus.
130. Molded prototypes: past, present and future.
131. Robot machines rapid prototype.
132. Options grow for fast mold tooling.
133. Teamworking wins the relay race.
134. Only connect.
135. Porsche model of perfection.
136. Rapid prototyping gets a desk job in the '90s.
137. Engineering online.
138. A systems approach to autonomous underwater vehicle (AUV) propulsion design.
139. Design and structure.
140. Flipper fever:.
141. Instant prototypes? Just about:.
142. Die casting: the whole works.
143. Stereolithography: taking CAD one step beyond.
144. Joining rapid prototyping at the HIP.
145. How to design in warp speed.
146. The business of making a supermodel.
147. Software for rapid prototyping (Maestro Workstation 1.7).
148. Streamlining a path to prototypes.
149. Data drives models in reverse.
150. Unraveling rapid prototyping methods.
151. Moldmakers take action to slash lead times.
152. New this year: 3D office modelers.
153. Forgings meet the challenges of the future.
154. Rapid growth in rapid prototyping.
155. Product developers must exploit the latest technology to compete.
156. It's a small world, after all.
157. High fibre.
158. A new dimension for office printers.
159. Maskless patterning can create micro-optics.
160. Rapid design and prototyping of customized rehabilitation aids.
161. Medical manufacturers adopt RP.
162. On the horizon: electrodes in a hurry.
163. Bad rap. (fossils aid in scientific discoveries)
164. RP slashes tooling from weeks to a day. (Xerox Corp. uses rapid prototyping with 3D Systems Corp. machine to make bearing)(Brief Article)
165. Rapid-prototyping method models full-scale cars.(Brief Article)
166. Researchers 'FAX' 3-D objects. (Stanford University creates three-dimensional computer model, transmits to 3-D Systems Corp.)(Brief Article)
167. Quick thinking: rapid prototyping is a hot topic right now, but how widely is it used in the industry?
168. Rapid prototyping and the IE. (industrial engineering)
169. Rapid prototyping for HIPing.(hot isostatic pressing)(Brief Article)
170. Prototyping as a production process.(the Research Institute at the University of Dayton is making use of rapid-prototyping to produce ceramic parts)(Emerging Technologies)(Brief Article)
171. Concept modeling in the design office.(3-D Systems Corp offers stereolithography peripheral for CAD workstations)(Brief Article)
172. Fashion models: compact and inexpensive, new office-friendly rapid-prototyping devices promise faster time to market, higher-quality new products, and more.
173. Texas-Based DTM Corp. Files for Public Stock Offering.(Originated from Austin American-Statesman, Texas)
174. Breaking the mold. (Helisys Inc.)(Company Profile)
175. Get with the program. (computer-aided design)
176. The road less traveled; going public on a foreign exchange.(Creative Financing)
177. Laying it on thin: desktop manufacturing.(three-dimensional printing of machine parts)
178. Low cuts his stake in Stratasys. (Nathan A. Low)
179. Dow Chemical forms alliance. (with Soane Technologies Inc.)
180. Helisys Inc. (New Securities Issues) Companies: Helisys Inc. - Securities
181. Net loss of about $400,000 is estimated in 2nd quarter. (Soligen Technologies Inc.)

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