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ME 521 Computer Aided Design 5. Rapid Prototyping

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Presentation on theme: "ME 521 Computer Aided Design 5. Rapid Prototyping"— Presentation transcript:

1 ME 521 Computer Aided Design 5. Rapid Prototyping
Assoc.Prof.Dr. Ahmet Zafer Şenalp Mechanical Engineering Department Gebze Technical University

2 Mechanical Engineering Department, GTU
5. Rapid Prototyping Rapid Prototyping It is the technology that using CAD models physical models are obtained directly. For this purpose rapid prototyping devices are used. Although rapid prototyping devices vary in its group their principles are the same. In this method physical models are formed by adding materials layer by layer. Rapid Prototyping (RP) brings solutions to the problems faced during product development period. Possible design mistakes can easily be identified. Before the mass production, prototype has to be prepared and several tests have to be conducted on these prototypes. This period may take a long time when conducted with conventional methods. With RP this period is shortened and prototypes can be tested both visually and functionally. Possible design changes can be decided on these prototypes and necessary changes can easily be made. Prototypes can be used for die manufacturing. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

3 Mechanical Engineering Department, GTU
5. Rapid Prototyping Rapid Prototyping Where are the parts produced by RP used? After visual inspection possible shape mistakes can be identified. For products that contain more than one part perfect assembly conditions (ex: alignment) can be checked. Mechanism functionality can be tested. An assembly with a lot of parts can be manufactured and run at one time. Prototypes can be used for die manufacturing . Prototype models can be used of precise casting. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

4 Mechanical Engineering Department, GTU
5. Rapid Prototyping Rapid Prototyping What kind of parts can be produced by RP? There is even no limitation to the parts that can be produced by RP. As the parts can easily be bonded to each other, the size of the part is not a problem. Die production can also be made with RP. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

5 Mechanical Engineering Department, GTU
5. Rapid Prototyping Rapid Prototyping How much time is needed for RP? Hours!... Time needed for RP depends on complexity and volume of the part. The delivery time is about 4-5 days after ordering. In special cases the period can be short as 1 day or long as 10 days. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

6 Mechanical Engineering Department, GTU
5. Rapid Prototyping Rapid Prototyping Is RP expensive? RP can be seen as expensive with the additional cost . However with RP the work that could be concluded in weeks can be finished in hours. Product defects can be detected earlier and much more expensive corrections can be avoided. With these advantages apparent cost for RP is less than the savings made by using RP. The RP cost of products depends on factors like product size, volume and geometry. Real cost of products should be determined after conducting necessary analysis. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

7 Mechanical Engineering Department, GTU
5. Rapid Prototyping Rapid Prototyping Rapid Prototyping Technologies: Polyjet FDM: Fused Deposition Modeling SLS: Selective Laser Sintering SLA: Stereolithography LOM: Laminated Object Manufacturing EBM: Electron Beam Melting 3-D Printing Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

8 Mechanical Engineering Department, GTU
5. Rapid Prototyping Polyjet In this technique, photo-polymer material in liquid form at room temperature is sprayed from spray nozzles of eight injection heads with thousands of injection spray nozzles which cause the formation of layers (similar to plastic injection machines). The sprayed material is freezed and solidified by using ultraviolet lamps. 16 micron thickness layers are formed one by one and prototype is obtained. As the model can not stop hanging in the air, the gaps are filled with support material with the same injection method. This support material then dissolves in water and the model is obtained. The materials used in this technology are photo-polymer resins which are specific to this method. Physical and chemical properties differ from each other. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

9 Mechanical Engineering Department, GTU
5. Rapid Prototyping Polyjet STL file is opened in the software and model is placed on the system’s table and the file is send to the Polyjet from the software. Polyjet system sprays the model and support material according to the instructions send by the software. After each layer sprayed material is applied ultraviolet rays for solidification. Model is constructed in 16 micron thickness layers. Then water spay is used to remove support material from the model and prototype is obtained. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

10 Mechanical Engineering Department, GTU
5. Rapid Prototyping Polyjet Polyjet Matrix Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

11 Polyjet 5. Rapid Prototyping Polyjet Product Examples: FullCure 720
Tango : TangoBlack & TangoGray Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

12 Polyjet 5. Rapid Prototyping Polyjet Product Examples: Tango plus
Vero : VeroBlue, VeroWhite, VeroBlack Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

13 FDM: Fused Deposition Modeling
5. Rapid Prototyping FDM: Fused Deposition Modeling Fused deposition modeling (FDM) is an additive manufacturing technology commonly used for modeling, prototyping, and production applications. The technology was developed by S. Scott Crump in the late 1980s and was commercialized in The FDM fused deposition model process is additive which extrudes material in layers. A plastic filament is melted and extruded through a heated nozzle. The nozzle moves to produce a profile of the part then moves down and the next layer is built on top until the entire prototype model is fully built. The model is complete and requires no hardening. FDM is an excellent choice for any 3D Model that needs to closely represent the final product in strength and durability. CAD Models can be produced in about 24 hours depending on the size and complexity. Online price quotes are available for FDM parts.. FDM requires support during the Prototype Model building process and can increase the build time. Several materials are available with different trade-offs between strength and temperature properties. As well as acrylonitrile butadiene styrene (ABS) polymer, polycarbonates, polycaprolactone, polyphenylsulfones and waxes. A "water-soluble" material can be used for making temporary supports while manufacturing is in progress, this soluble support material is quickly dissolved with specialized mechanical agitation equipment utilizing a precisely heated sodium hydroxide solution.. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

14 FDM: Fused Deposition Modeling
5. Rapid Prototyping FDM: Fused Deposition Modeling Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

15 FDM: Fused Deposition Modeling
5. Rapid Prototyping FDM: Fused Deposition Modeling Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

16 FDM: Fused Deposition Modeling
5. Rapid Prototyping FDM: Fused Deposition Modeling FDM Product Examples: Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

17 SLS: Selective Laser Sintering
5. Rapid Prototyping SLS: Selective Laser Sintering Laser Sintering is also a technique by which parts are built layer by layer. The basic material consists of powder with particle sizes in the order of magnitude of 50 µm. Successive powder layers are spread on top of each other. After deposition, a computer controlled CO2 laser beam scans the surface and selectively binds together the powder particles of the corresponding cross section of the product. During laser exposure, the powder temperature rises above the glass transition point after which adjacent particles flow together. This process is called sintering. After production of the part is completed powders that function as support material are cleaned by a brush. The material those are used in this technology are Polyamide, Ploystrene and several metal alloys. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

18 SLS: Selective Laser Sintering
5. Rapid Prototyping SLS: Selective Laser Sintering SLS Working Principle: In sintering powder material is left under the melting temperature of the material so that powders stick to each other. 4 phases of sintering can be seen in the above figure. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

19 SLS: Selective Laser Sintering
5. Rapid Prototyping SLS: Selective Laser Sintering Best application areas of SLS technology Mechanical and thermal test parts Plastic parts Large complex functional parts Casting parts Functional models SLS Advantages Products are resistant to shape and functional tests Parts can be assembled with mechanic or chemical methods No need to use support material Parts are cleaner than other methods Heat treatment or painting can be applied on the parts The materials used plastic, metal or ceramic powders can be used, as well as their mixtures consisting of composite powders are also available. Glass fiber reinforced plastic powders or plastic-coated metal powders are examples to this. In the case of metal usage the method is called as Direct Metal Laser Sintering (DMLS). Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

20 SLS: Selective Laser Sintering
5. Rapid Prototyping SLS: Selective Laser Sintering Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

21 SLS: Selective Laser Sintering
5. Rapid Prototyping SLS: Selective Laser Sintering Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

22 SLS: Selective Laser Sintering
5. Rapid Prototyping SLS: Selective Laser Sintering SLS Product Examples: Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

23 SLS: Selective Laser Sintering
5. Rapid Prototyping SLS: Selective Laser Sintering SLS Product Examples: Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

24 SLS: Selective Laser Sintering
5. Rapid Prototyping SLS: Selective Laser Sintering SLS Advantages SLS polyamide (nylon) material enables full functional prototype production. Glass-filled nylon is resistant to high temperature and chemical environments in the prototype production. Rubber like parts can be manufactured directly from polymer. This is for seals and sealing elements that are exposed to high temperature. For durable metal parts and molded parts P20 steel which is similar to St 200 can be used. SLS Disadvantages The surface finish of SLS parts are not good as SLA parts but additional surface finish can be applied. High shrinkage ratios can result torsion, bending or dimensional inaccuracy. SLS feature details are not precise as in SLA. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

25 SLA: Stereolithography
5. Rapid Prototyping SLA: Stereolithography Stereolithography is an additive manufacturing process using a vat of liquid UV-curable photopolymer "resin" and a UV laser to build parts a layer at a time. On each layer, the laser beam traces a part cross-section pattern on the surface of the liquid resin. Exposure to the UV laser light cures, or, solidifies the pattern traced on the resin and adheres it to the layer below. After a pattern has been traced, the SLA's elevator platform descends by a single layer thickness, typically 0.05 mm to 0.15 mm (0.002" to 0.006"). Then, a resin-filled blade sweeps across the part cross section, re-coating it with fresh material. On this new liquid surface, the subsequent layer pattern is traced, adhering to the previous layer. A complete 3-D part is formed by this process. After building, parts are cleaned of excess resin by immersion in a chemical bath and then cured in a UV oven. Stereolithography requires the use of support structures to attach the part to the elevator platform and to prevent certain geometry from not only deflecting due to gravity, but to also accurately hold the 2-D cross sections in place such that they resist lateral pressure from the re-coater blade. Supports are generated automatically during the preparation of 3-D CAD models for use on the stereolithography machine, although they may be manipulated manually. Supports must be removed from the finished product manually; this is not true for all rapid prototyping technologies. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

26 SLA: Stereolithography
5. Rapid Prototyping SLA: Stereolithography Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

27 SLA: Stereolithography
5. Rapid Prototyping SLA: Stereolithography Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

28 SLA: Stereolithography
5. Rapid Prototyping SLA: Stereolithography Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

29 SLA: Stereolithography
5. Rapid Prototyping SLA: Stereolithography SLA Part Examples: Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

30 SLA: Stereolithography
5. Rapid Prototyping SLA: Stereolithography SLA Part Examples: Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

31 LOM:Laminated Object Manufacturing
5. Rapid Prototyping LOM:Laminated Object Manufacturing Laminated object manufacturing (LOM) is a rapid prototyping system developed by Helisys Inc. In it, layers of adhesive-coated paper, plastic, or metal laminates are successively glued together and cut to shape with a knife or laser cutter. The process is performed as follows: Sheet is adhered to a substrate with a heated roller. Laser traces desired dimensions of prototype. Laser cross hatches non-part area to facilitate waste removal. Platform with completed layer moves down out of the way. Fresh sheet of material is rolled into position. Platform moves up into position to receive next layer. The process is repeated. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

32 LOM:Laminated Object Manufacturing
5. Rapid Prototyping LOM:Laminated Object Manufacturing Advantages Low cost due to readily available raw material Relatively large parts may be made, because no chemical reaction is necessary Fast as laser only traces the contour and does not trace the whole cross section. Parts can be used immediately after processing. There is no need for Additional processing. No need for additional support. It is easy to use. Disadvantages The most common used material is still paper. The materials on any other specified is currently underway. As parts are easily to accommodate to humidity finishing should be applied with a special Epoxy based material (Lompoxy: generated for LOM usage). Production of complex parts are difficult. There may be fire problem when the working zone gets too hot. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

33 LOM:Laminated Object Manufacturing
5. Rapid Prototyping LOM:Laminated Object Manufacturing Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

34 LOM:Laminated Object Manufacturing
5. Rapid Prototyping LOM:Laminated Object Manufacturing LOM Part Examples: Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

35 LOM:Laminated Object Manufacturing
5. Rapid Prototyping LOM:Laminated Object Manufacturing Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

36 EBM:Electron Beam Melting
5. Rapid Prototyping EBM:Electron Beam Melting Electron beam melting (EBM) is a type of additive manufacturing for metal parts. The technology manufactures parts by melting metal powder layer per layer with an electron beam in a high vacuum. Unlike some metal sintering techniques, the parts are fully dense, void-free, and extremely strong. The vacuum environment in the EBM machine maintains the chemical composition of the material and provides an excellent environment for building parts with reactive materials such as titanium alloys. The electron beam’s high power ensures a high rate of deposition and an even temperature distribution within the part, which gives a fully melted metal with excellent mechanical and physical properties. . Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

37 EBM:Electron Beam Melting
5. Rapid Prototyping EBM:Electron Beam Melting Part surface quality is very good compared to other RP methods. Can be applicable to metals, materials apart from metals, ceramics and composite materials. EBM is successful in small and parts with precise regions. Can drill holes with one or two nanometer precision. More precise than metal cutting operations. The part can directly be used after the operation. No need for extra heat treatment SLS,LSM,DMLS needs heat treatment. Due to high energy and scanning method EBM is very fast. Minimum layer thickness: 0.05 mm Tolerance: +/-0,4 mm. Very successful in titanium alloys. Applied to medical implants, aerospace/automotive parts successfully. In this method parts are produced within hours. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

38 EBM:Electron Beam Melting
5. Rapid Prototyping EBM:Electron Beam Melting Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

39 EBM:Electron Beam Melting
5. Rapid Prototyping EBM:Electron Beam Melting EBM application with Ti6AI4V material Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

40 EBM:Electron Beam Melting
5. Rapid Prototyping EBM:Electron Beam Melting Advantages Obtaining high energy with narrow beam. The quality of the vacuum melting enables high material properties. Vacuum environment avoids oxide and nitride based impurities. Enables welding of unlike metals that are hard to process. Comparison with SLS: Due to efficient beam formation power consumption is low Maintenance and installation costs are lower It has high power and speed Bending of the beam is obtained without moving the part which results high speed and low maintenance. Disadvantages Vacuum requirement means additional cost. Emits gamma rays during operation (Vacuum tanks should be designed to protect rays) Materials should have electric conductive property. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

41 EBM:Electron Beam Melting
5. Rapid Prototyping EBM:Electron Beam Melting EBM Part Examples: Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

42 Mechanical Engineering Department, GTU
5. Rapid Prototyping 3D Printing Developed in MIT (Massachusetts Institute of Technology). 3D parts is produced layer by layer. 3D printers are generally fast and have low cost. One version of 3D printing includes inkjet printing system. Fine dust material (plaster, resin) is sprayed from the printer and adhesive is then used for bonding. This technology enables the production of fully colorful prototypes. Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

43 Mechanical Engineering Department, GTU
5. Rapid Prototyping 3-D Printing Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

44 Mechanical Engineering Department, GTU
5. Rapid Prototyping 3-D Printing Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

45 Mechanical Engineering Department, GTU
5. Rapid Prototyping 3-D Printing 3-D Printing Part Examples: Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU

46 RP Technology comrarison
5. Rapid Prototyping Rapid Prototyping RP Technology comrarison (lower grade is better) Dr. Ahmet Zafer Şenalp ME 521 Mechanical Engineering Department, GTU


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