logging in or signing up Rapid Prototyping anjaiah19 Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT lite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 128 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: January 04, 2012 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Rapid Prototyping : Rapid Prototyping Dr. Lotfi K. Gaafar The American University in Cairo Department of Mechanical Engineering gaafar@aucegypt.edu (202) 797-5355Introduction: Introduction Rapid Prototyping (RP) techniques are methods that allow designers to produce physical prototypes quickly. It consists of various manufacturing processes by which a solid physical model of part is made directly from 3D CAD model data without any special tooling. The first commercial rapid prototyping process was brought on the market in 1987. Nowadays, more than 30 different processes (not all commercialized) with high accuracy and a large choice of materials exist. These processes are classified in different ways: by materials used, by energy used, by lighting of photopolymers, or by typical application range.The Rapid Prototyping Technique: The Rapid Prototyping Technique In the Rapid Prototyping process the 3D CAD data is sliced into thin cross sectional planes by a computer. The cross sections are sent from the computer to the rapid prototyping machine which build the part layer by layer . The first layer geometry is defined by the shape of the first cross sectional plane generated by the computer. It is bonded to a starting base and additional layers are bonded on the top of the first shaped according to their respective cross sectional planes. This process is repeated until the prototype is complete.Rapid Prototyping Technique: Rapid Prototyping Technique Process Flow 3D Solid modeling Data preparation Part Building Redesign Pass RejectPrototyping- What is it ?: Prototyping- What is it ? . Physical Model of the product . Degrees of Prototyping . Full Complete scale Model - functional model . Scaled Model - functional/ simulated material . Geometrical configuration . Partial ….Prototyping- Why? : Prototyping- Why? Visualization Design Change (iterations) Free Form Prototyping (complex object fabrication/ visualization) Testing Fit/ Packaging Cost, Time, and resource estimation Process Planning First to Market -- Critical for today’s industry Rapid production (concurrent activities) JIT concept (0 Inventory) Rapid tooling / no tooling -- trend in technologyPrototyping- Why? : Design verification Design for manufacturability Design for assembly Design for maintainability Design for reliability Design for Quality Design Parameters (Tolerances/ allowances) Concurrent Engineering Tooling . Reverse Engineering . Die fabrication . Tool Path generation Limited Production Prototyping- Why?Classification of Prototyping Technology : Classification of Prototyping Technology Subtractive Processes (Material Removal) Ex : Milling, turning, grinding,-- machining centers .., when used for prototype production Degree of automation vary Additive (Material Build-up) Ex : Stereolithography Degree of sophistication vary Formative (Sculpture) Ex : Forging, Casting, .. When used for Prototyping, it is usually manualSophistication of Prototyping Technology : Such Technology is known by different terms, such as : Desktop Manufacturing Rapid Prototyping Tool-less Manufacturing 3-D printing Free form Fabrication (F 3 ) Sophistication of Prototyping TechnologySophistication of Prototyping Technology : Sophistication of Prototyping Technology Fabrication process : The process must take a material in some shapeless form, and turn out solid objects with definite shape Degree of Automation : High degree of automation. Since Prototyping is a stage in a cycle, it is expected that the technology will enable “automated chaining” to the before and after links in the cycle. Ability to build complex objects The more complex the build object, the more sophistication in the technology.Sophistication of Prototyping Technology : Tooling (no Tooling): Less tools is better One shot operations: No assembly of parts, ..etc. Time: The less time the better it is The closeness to serve the purpose of the prototype: Accurate representation of the design Flexible: Modifications, addition of parameters, scaling Equipment: size, weight, maintenance..etc Economical: Both equipment and operating costs Clean, safe operation User friendly Sophistication of Prototyping TechnologyRapid Prototyping Processes: Rapid Prototyping Processes SLS --- Selective Laser Sintering SLA --- Stereolithography LOM --- Laminated Object Manufacturing FDM --- Fused Deposition Modeling OthersRapid prototyping Processes- SLS: Rapid prototyping Processes- SLS Selective Laser SinteringRapid prototyping Processes- SLS: Application Range Visual Representation models Functional and tough prototypes cast metal parts Advantages Flexibility of materials used PVC, Nylon, Sand for building sand casting cores, metal and investment casting wax. No need to create a structure to support the part Parts do not require any post curing except when ceramic is used. Disadvantages During solidification, additional powder may be hardened at the border line. The roughness is most visible when parts contain sloping (stepped) surfaces. Rapid prototyping Processes- SLSRapid prototyping Processes- SL: Rapid prototyping Processes- SL StereolithographyRapid Prototyping Resin: Rapid Prototyping Resin Basic Polymer Chemistry SL Resin : It is a liquid photocurable resin Characteristics Fully 100% reactive component Energy efficient requiring 50 to 100 times less energy than thermally cured coatings Polymerization : It is the process of linking small molecules (monomers) into larger molecules (polymers) comprised of many monomer units. As polymerization occurs (chemical reaction) many properties changes, shear strength increase, density increased as resin changes from liquid to solid (shrinkage) Polymerization occurs in SL through the exposure of liquid resin to laser. The layer thickness to be polymerized is given by the amount of liquid which has been recoated onto the part, and any excess laser radiation that penetrates this layer acts to slightly increase the curing of the previous layers. The important properties for selecting the resin has to do with posture shrinkage and the resulting posture distortions.Desirable features of SL resin: Desirable features of SL resin Improved Impact resistance (less brittleness) Greater Flexibility Improved photospeed Increased Strength Better overall part accuracy Electrical conductivity High temperature resistance Solvent resistance or vice versaSome measures to reduce distortions: Some measures to reduce distortions Use high exposure and slow scan speed such that polymerization is essentially complete under the laser spot. Use resin with a faster rate of polymerization Decrease laser power to decrease scan speed for a given exposure. Use low-shrinkage resin Increase layer thickness to increase the strengthRapid prototyping Processes- SL: Application Range Parts used for functional tests Manufacturing of medical models Form –fit functions for assembly tests Advantages Possibility of manufacturing parts which are impossible to be produced conventionally in a single process Can be fully atomized and no supervision is required. High Resolution No geometric limitations Disadvantages Necessity to have a support structure Require labor for post processing and cleaning Rapid prototyping Processes- SLRapid prototyping Processes- LOM: Rapid prototyping Processes- LOM Laminated Object ManufacturingRapid prototyping Processes- LOM: Application Range Visual Representation models Large Bulky models as sand casting patterns Advantages Variety of organic and inorganic materials can be used Paper, plastic, ceramic, composite Process is faster than other processes No internal stress and undesirable deformations LOM can deal with discontinuities, where objects are not closed completely Disadvantages The stability of the object is bonded by the strength of the glued layers. Parts with thin walls in the z direction can not be made using LOM Hollow parts can not be built using LOM Rapid prototyping Processes- LOMPowerPoint Presentation: Rapid prototyping Processes- FDM Fused Deposition ModelingPowerPoint Presentation: Rapid prototyping Processes- FDMPowerPoint Presentation: Application Range Conceptual modeling Fit, form applications and models for further manufacturing procedures Investment casting and injection molding Advantages Quick and cheap generation of models There is no worry of exposure to toxic chemicals, lasers or a liquid chemical bath. Disadvantages Restricted accuracy due to the shape of material used, wire is 1.27 mm diameter. Rapid prototyping Processes- FDMPowerPoint Presentation: Other Processes Ballistic Particle Manufacturing (BPM) This process uses a 3D solid model data to direct streams of material at a target. 3D Printing It creates parts by layered printing process. The layers are produced by adding a layer of powder to the top of a piston and cylinder containing a powder bed and the part is being fabricated. Model Maker It uses ink jet printer technology with 2 heads. One deposits building material, and the other deposits supporting wax. Rapid prototyping ProcessesRapid Prototyping Products: Rapid Prototyping Products You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
Rapid Prototyping anjaiah19 Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT lite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 128 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: January 04, 2012 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Rapid Prototyping : Rapid Prototyping Dr. Lotfi K. Gaafar The American University in Cairo Department of Mechanical Engineering gaafar@aucegypt.edu (202) 797-5355Introduction: Introduction Rapid Prototyping (RP) techniques are methods that allow designers to produce physical prototypes quickly. It consists of various manufacturing processes by which a solid physical model of part is made directly from 3D CAD model data without any special tooling. The first commercial rapid prototyping process was brought on the market in 1987. Nowadays, more than 30 different processes (not all commercialized) with high accuracy and a large choice of materials exist. These processes are classified in different ways: by materials used, by energy used, by lighting of photopolymers, or by typical application range.The Rapid Prototyping Technique: The Rapid Prototyping Technique In the Rapid Prototyping process the 3D CAD data is sliced into thin cross sectional planes by a computer. The cross sections are sent from the computer to the rapid prototyping machine which build the part layer by layer . The first layer geometry is defined by the shape of the first cross sectional plane generated by the computer. It is bonded to a starting base and additional layers are bonded on the top of the first shaped according to their respective cross sectional planes. This process is repeated until the prototype is complete.Rapid Prototyping Technique: Rapid Prototyping Technique Process Flow 3D Solid modeling Data preparation Part Building Redesign Pass RejectPrototyping- What is it ?: Prototyping- What is it ? . Physical Model of the product . Degrees of Prototyping . Full Complete scale Model - functional model . Scaled Model - functional/ simulated material . Geometrical configuration . Partial ….Prototyping- Why? : Prototyping- Why? Visualization Design Change (iterations) Free Form Prototyping (complex object fabrication/ visualization) Testing Fit/ Packaging Cost, Time, and resource estimation Process Planning First to Market -- Critical for today’s industry Rapid production (concurrent activities) JIT concept (0 Inventory) Rapid tooling / no tooling -- trend in technologyPrototyping- Why? : Design verification Design for manufacturability Design for assembly Design for maintainability Design for reliability Design for Quality Design Parameters (Tolerances/ allowances) Concurrent Engineering Tooling . Reverse Engineering . Die fabrication . Tool Path generation Limited Production Prototyping- Why?Classification of Prototyping Technology : Classification of Prototyping Technology Subtractive Processes (Material Removal) Ex : Milling, turning, grinding,-- machining centers .., when used for prototype production Degree of automation vary Additive (Material Build-up) Ex : Stereolithography Degree of sophistication vary Formative (Sculpture) Ex : Forging, Casting, .. When used for Prototyping, it is usually manualSophistication of Prototyping Technology : Such Technology is known by different terms, such as : Desktop Manufacturing Rapid Prototyping Tool-less Manufacturing 3-D printing Free form Fabrication (F 3 ) Sophistication of Prototyping TechnologySophistication of Prototyping Technology : Sophistication of Prototyping Technology Fabrication process : The process must take a material in some shapeless form, and turn out solid objects with definite shape Degree of Automation : High degree of automation. Since Prototyping is a stage in a cycle, it is expected that the technology will enable “automated chaining” to the before and after links in the cycle. Ability to build complex objects The more complex the build object, the more sophistication in the technology.Sophistication of Prototyping Technology : Tooling (no Tooling): Less tools is better One shot operations: No assembly of parts, ..etc. Time: The less time the better it is The closeness to serve the purpose of the prototype: Accurate representation of the design Flexible: Modifications, addition of parameters, scaling Equipment: size, weight, maintenance..etc Economical: Both equipment and operating costs Clean, safe operation User friendly Sophistication of Prototyping TechnologyRapid Prototyping Processes: Rapid Prototyping Processes SLS --- Selective Laser Sintering SLA --- Stereolithography LOM --- Laminated Object Manufacturing FDM --- Fused Deposition Modeling OthersRapid prototyping Processes- SLS: Rapid prototyping Processes- SLS Selective Laser SinteringRapid prototyping Processes- SLS: Application Range Visual Representation models Functional and tough prototypes cast metal parts Advantages Flexibility of materials used PVC, Nylon, Sand for building sand casting cores, metal and investment casting wax. No need to create a structure to support the part Parts do not require any post curing except when ceramic is used. Disadvantages During solidification, additional powder may be hardened at the border line. The roughness is most visible when parts contain sloping (stepped) surfaces. Rapid prototyping Processes- SLSRapid prototyping Processes- SL: Rapid prototyping Processes- SL StereolithographyRapid Prototyping Resin: Rapid Prototyping Resin Basic Polymer Chemistry SL Resin : It is a liquid photocurable resin Characteristics Fully 100% reactive component Energy efficient requiring 50 to 100 times less energy than thermally cured coatings Polymerization : It is the process of linking small molecules (monomers) into larger molecules (polymers) comprised of many monomer units. As polymerization occurs (chemical reaction) many properties changes, shear strength increase, density increased as resin changes from liquid to solid (shrinkage) Polymerization occurs in SL through the exposure of liquid resin to laser. The layer thickness to be polymerized is given by the amount of liquid which has been recoated onto the part, and any excess laser radiation that penetrates this layer acts to slightly increase the curing of the previous layers. The important properties for selecting the resin has to do with posture shrinkage and the resulting posture distortions.Desirable features of SL resin: Desirable features of SL resin Improved Impact resistance (less brittleness) Greater Flexibility Improved photospeed Increased Strength Better overall part accuracy Electrical conductivity High temperature resistance Solvent resistance or vice versaSome measures to reduce distortions: Some measures to reduce distortions Use high exposure and slow scan speed such that polymerization is essentially complete under the laser spot. Use resin with a faster rate of polymerization Decrease laser power to decrease scan speed for a given exposure. Use low-shrinkage resin Increase layer thickness to increase the strengthRapid prototyping Processes- SL: Application Range Parts used for functional tests Manufacturing of medical models Form –fit functions for assembly tests Advantages Possibility of manufacturing parts which are impossible to be produced conventionally in a single process Can be fully atomized and no supervision is required. High Resolution No geometric limitations Disadvantages Necessity to have a support structure Require labor for post processing and cleaning Rapid prototyping Processes- SLRapid prototyping Processes- LOM: Rapid prototyping Processes- LOM Laminated Object ManufacturingRapid prototyping Processes- LOM: Application Range Visual Representation models Large Bulky models as sand casting patterns Advantages Variety of organic and inorganic materials can be used Paper, plastic, ceramic, composite Process is faster than other processes No internal stress and undesirable deformations LOM can deal with discontinuities, where objects are not closed completely Disadvantages The stability of the object is bonded by the strength of the glued layers. Parts with thin walls in the z direction can not be made using LOM Hollow parts can not be built using LOM Rapid prototyping Processes- LOMPowerPoint Presentation: Rapid prototyping Processes- FDM Fused Deposition ModelingPowerPoint Presentation: Rapid prototyping Processes- FDMPowerPoint Presentation: Application Range Conceptual modeling Fit, form applications and models for further manufacturing procedures Investment casting and injection molding Advantages Quick and cheap generation of models There is no worry of exposure to toxic chemicals, lasers or a liquid chemical bath. Disadvantages Restricted accuracy due to the shape of material used, wire is 1.27 mm diameter. Rapid prototyping Processes- FDMPowerPoint Presentation: Other Processes Ballistic Particle Manufacturing (BPM) This process uses a 3D solid model data to direct streams of material at a target. 3D Printing It creates parts by layered printing process. The layers are produced by adding a layer of powder to the top of a piston and cylinder containing a powder bed and the part is being fabricated. Model Maker It uses ink jet printer technology with 2 heads. One deposits building material, and the other deposits supporting wax. Rapid prototyping ProcessesRapid Prototyping Products: Rapid Prototyping Products