3D Printing and Digital Designing Samples †MyAssignmenthelp.com

Question: Discuss about the 3D Printing and Digital Designing. Answer: Introduction 3D printing works over the digital designing where the model is to create a proper modelling software where the data is generated with the 3D scanner. This helps in working over the blender and handling the slicing which is for the 3D model into different horizontal layers which is important as well. This is also important to force the use of different slicing tools for the 3D printer where the scanner is used layer by layer to work for processing the video. The 3D printing is important for the consumer goods, industrial, high tech services and the health care sectors as well (Campbell et al., 2011). This is through becoming intertwined through the daily operations with the use of 3D printing structures where the company focus on the research, development and prototyping as well. 3D printing also called additive manufacturing This is so mainly because it creates the physical objects from the digital designing. There are different technologies and the materials that could be used for the printing and to handle the digital models that are set to turn into the solid 3-D physical objects by addition of the material layer by layer. With this, for every object, there is a need of printing the documents over the paper where the printing process mainly varies by the technology. This refers to the process of creating the layers of material which are under the computer control to create the objects. Here, the objects can easily be set with the production using the digital model data from the 3D model (Weller et al, 2015). The standards are set for the material which are removed from the stock in the conventional machining process where the AM tends to work from the CAD designing or the AMF files by the addition of the material layer by layer. Is 3D printing better suited for high or low volumes of production It is important to focus on the different production range where the low volume manufacturing could leverage the companies of different side. Here, the focus is on: Lowering the volume with the manufacturing that save the money. It works on the standards when it comes to the cost per unit which is depending upon the materials that is being used. The tools are set with the different range of carbon and alloy steels that are found to be hard, where the low manufacturing could set upto 100,000 pieces where there is a great way to avoid the large investments as well. The larger production of the facilities is mainly imposing the minimised order requirements of offset with the heavy production investments. The low volume also gives a major designing flexibility which is set for the refining of the consumer feedback (Rengier et al. 2010). It also ensures the faster time for the marketing where the high competition is set with the fickle market that leads to the increased pressure on the developers and the designers as well. Hence, the ability to get the market is to capitalise on the consumer trends and work over the ability to develop and reduce the risks factors as well. The option is also for the bridge production where the market is quick and allow the companies to produce the up-front costs and time of mass production as well. Situations where 3D printing important The 3D printing is important for the manufacturing of applications with the focus on mass customisation produced with the based material on the full colour of the 3D inkjet printer. This is also used in the additive manufacturing of the food into 3D objects like the chocolates and the candy etc. The medical applications make use of the 3D printing for the surgery where the virtual planning is mainly applied in the areas which include the creation of the unique and the patient matched devices for rare illness. The bio-printing is also considered to be done through this where the applications are set under the field of research with organ printing, bio printing and the body party printing. The possibility is to use the 3D tissue which is mainly to create the soft tissue for the reconstructive surgery. The industrial applications like the apparels make use for the custom fit and the styling (Lam et al., 2002). This is mainly on-demand customisation of the glasses with the rapid prototyp ing. Here, the industrial art and the jewellery makes use of the personalised models of the art and the dolls. There are different shapes in metal or plastic with the consumable art like the 3D printed chocolates. The construction and the firearms make use of the 3D printing to produce the scale models with the architecture that has the increased stability with the reduced costs of the 3D printers. The applications are to fabricate and work on the entire designing, development of the new technologies as well. Research and investment firms forecast for 3D printing As per the market forecast, the GE plans to work on mass production with LEAP Engine nozzles with the forecasting of the growth by the equity research. The 3D printing works on the acceleration of the product development with customised products with increased production flexibility (Bak, 2003). The improved spare parts managements work on accelerating and offering the customised products. The companies tend to work over the compeititve advantage in the strategy where the predictive standards are to lead with average budget for 3D printing that range from $6132 in 2016 to $9504 in 2017. There is different technology to offer the high-end system features from one factor at the lower pricing points (Schubert et al., 2014). The printer speeds are increased with the product spectrum under the development where the rapid prototyping is set with market research firms. The anticipation changes and predict from the global market for the services that tends to grow from $2.5 billion in 2013 to $16.2 billion in 2018. 3D printing for traditional manufacturing obsolete The 3D printing works on: The waste prevention where manufacturers work over compelling and overproducing the different reasons that results to waste in the long run. This will also allow the production with the proper quantity without any loss. The easy prototype production works on allowing into production with assembling the designs. The focus is on affordable laser cutting machinery is set with working over the specialised computer programs to the system for production. This is set for retooling the production machine in the traditional manufacturing (Leigh et al., 2012). The seamless production works over the automation with the manual input set which is same as in the case of traditional manufacturing. The automation process is set without rigorous manual input. The items are set and categorised with the finished products into the seamless process. The standards are set to prompt the printer with stopping the events and avoiding and production hazards as well. The mass customisation with the customised designs can easily be printed with the larger quantities that is set at the extra cost (Hoy, 2013). Recommendation The 3D printing should work over the advocacy of the technology development where the technology should try to increase the ability of manufacturing and production runs with customised work pieces. The use of the plastic injection modelling is also important for the mass production which is printed on the industrial 3D printers which allow the selling of products with smaller production running at a profit. For this, there is a need to focus on the safety ideals with the strength for the 3D products. This will help in improving the quality and work for a long time as well. Conclusion The 3D printers work over the access to the consumers, with the online platforms to support the community. It includes the websites that allow the users to properly access the information with building the 3D printer (Rayna et al., 2015). With this, there is a major focus on the low-cost manufacturing that allows the decreased cost of transactions. Here, the websites have also been able to allow the greater standards with social interaction between the users and then creating communities which are dedicated to the 3D printing. The question is about the recycling of the advancement nanomaterials with the common based peer production that leads to the economy of scope. References Bak, D., 2003. Rapid prototyping or rapid production? 3D printing processes move industry towards the latter.Assembly Automation,23(4), pp.340-345. Campbell, T., Williams, C., Ivanova, O. and Garrett, B., 2011. Could 3D printing change the world.Technologies, Potential, and Implications of Additive Manufacturing, Atlantic Council, Washington, DC. Hoy, M.B., 2013. 3D printing: making things at the library.Medical reference services quarterly,32(1), pp.93-99. Lam, C.X.F., Mo, X.M., Teoh, S.H. and Hutmacher, D.W., 2002. Scaffold development using 3D printing with a starch-based polymer.Materials Science and Engineering: C,20(1), pp.49-56. Leigh, S.J., Bradley, R.J., Purssell, C.P., Billson, D.R. and Hutchins, D.A., 2012. A simple, low-cost conductive composite material for 3D printing of electronic sensors.PloS one,7(11), p.e49365. Rayna, T., Striukova, L. and Darlington, J., 2015. Co-creation and user innovation: The role of online 3D printing platforms.Journal of Engineering and Technology Management,37, pp.90-102. Rengier, F., Mehndiratta, A., von Tengg-Kobligk, H., Zechmann, C.M., Unterhinninghofen, R., Kauczor, H.U. and Giesel, F.L., 2010. 3D printing based on imaging data: review of medical applications.International journal of computer assisted radiology and surgery,5(4), pp.335-341. Schubert, C., Van Langeveld, M.C. and Donoso, L.A., 2014. Innovations in 3D printing: a 3D overview from optics to organs.British Journal of Ophthalmology,98(2), pp.159-161. Weller, C., Kleer, R. and Piller, F.T., 2015. Economic implications of 3D printing: Market structure models in light of additive manufacturing revisited.International Journal of Production Economics,164, pp.43-56.