Relevant bibliographies by topics / 3D printing architecture

Academic literature on the topic '3D printing architecture'

Author: Grafiati
Published: 10 December 2022
Last updated: 28 January 2023

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Journal articles on the topic "3D printing architecture"

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Saleh Abd Elfatah, Ahmed. "3D Printing in Architecture, Engineering and Construction (Concrete 3D printing)." Engineering Research Journal 162 (June 1, 2019): 119–37. http://dx.doi.org/10.21608/erj.2019.139808.

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Talyosef, Orly. "Perspectives on BIM-Based 3D Printing for Sustainable Buildings." Architext 9 (2021): 36–52. http://dx.doi.org/10.26351/architext/9/3.

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Three-dimensional (3D) printing, also called additive manufacture (AM), is a novel, automated method of printing a structure layer-by-layer directly from a 3D digital design model. Its potential ability to build complex shapes in a less costly and more sustainable manner may revolutionize the construction industry. There are three main 3D printing techniques: (a) contour crafting; (b) concrete printing, and (c) D-shape. As a disruptive technology, 3D printing creates a new market and value network, thus disturbing the established market. Building information modeling (BIM) is a comprehensive management approach encompassing the entire life cycle of the architecture and construction (A&C) process, including architectural planning, geometrical data, scheduling, material, equipment, resource and manufacturing data, and post-construction facility management. By maintaining safety and productivity in large-scale digital processes, BIM is critical to 3D printing’s success in construction. Integrating BIM and 3D printing techniques into A&C can potentially lead to an ecological architectural process that reduces waste and energy inefficiency, and prevents injuries and fatalities on construction sites, while increasing productivity and quality. This paper examines BIM-based 3D printing of sustainable buildings, which may revolutionize the construction industry and contribute to a sustainable environment
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Song, Min Jeong, Euna Ha, Sang-Kwon Goo, and JaeKyung Cho. "Design and Development of 3D Printed Teaching Aids for Architecture Education." International Journal of Mobile and Blended Learning 10, no. 3 (July 2018): 58–75. http://dx.doi.org/10.4018/ijmbl.2018070106.

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This article describes how the implementation of 3D printing in classrooms has brought many opportunities to educators as it provides affordability and accessibility in creating and customizing teaching aids. The study reports on the process of fabricating teaching aids for architecture education using 3D printing technologies. The practice-based research intended to illustrate the making process from initial planning, 3D modeling to 3D printing with practical examples, and addresses the potential induced by the technologies. Based on the investigation into the current state of 3D printing technologies in education, limitations were identified before the making process. The researchers created 3D models in both digital and tangible forms and the process was documented in textual and pictorial formats. It is expected that the research findings will serve as a guideline for other educators to create 3D printed teaching aids, particularly architectural forms.
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García-Alvarado, Rodrigo, Claudia Muñoz-Sanguinetti, Alejandro Martínez-Rocamora, and Ginnia Moroni Orellana. "Condiciones arquitectónicas de la construcción impresa-3D." AUS, no. 32 (2022): 20–30. http://dx.doi.org/10.4206/aus.2022.n32-04.

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Nicholas, Paul, Gabriella Rossi, Ella Williams, Michael Bennett, and Tim Schork. "Integrating real-time multi-resolution scanning and machine learning for Conformal Robotic 3D Printing in Architecture." International Journal of Architectural Computing 18, no. 4 (August 13, 2020): 371–84. http://dx.doi.org/10.1177/1478077120948203.

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Robotic 3D printing applications are rapidly growing in architecture, where they enable the introduction of new materials and bespoke geometries. However, current approaches remain limited to printing on top of a flat build bed. This limits robotic 3D printing’s impact as a sustainable technology: opportunities to customize or enhance existing elements, or to utilize complex material behaviour are missed. This paper addresses the potentials of conformal 3D printing and presents a novel and robust workflow for printing onto unknown and arbitrarily shaped 3D substrates. The workflow combines dual-resolution Robotic Scanning, Neural Network prediction and printing of PETG plastic. This integrated approach offers the advantage of responding directly to unknown geometries through automated performance design customization. This paper firstly contextualizes the work within the current state of the art of conformal printing. We then describe our methodology and the design experiment we have used to test it. We lastly describe the key findings, potentials and limitations of the work, as well as the next steps in this research.
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Rodrigues Carneiro, Luiz Renato, and José Jean-Paul Zanlucchi de Souza Tavares. "Design and implementation of 3D printer for Mechanical Engineering Courses." International Journal for Innovation Education and Research 9, no. 3 (March 1, 2021): 293–312. http://dx.doi.org/10.31686/ijier.vol9.iss3.3001.

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Nowadays 3D printing is a hot topic and this was specially observed during the COVID-19 pandemic. Hence, this project has the objective to present the design and implementation of a 3D printer, which fits the Mechanical Engineering Courses requisites. The founded solution follows the Delta architecture and it was called Delta MAPL. This paper will summarize all important definitions and knowledge to build a 3D printer such as, 3D printers technologies and architectures, expose the developed project involving mechanic and electric project, project cost, programming and slicer, calibration, printing parameters, and will also expose de results through implementation of the project, 3D printing tests, and also the documentation with all design parts, codes and printing parameters. Therefore, 3D printer is very useful and involving many fields of Mechanical Engineering knowledge, thus 3D printing develops not only knowledge in mechanic, electric, sensors and actuators and material properties, but also creativity and problem-solving that are so important for all engineering students.
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Chu, Tiankuo, Soyeon Park, and Kun (Kelvin) Fu. "3D printing‐enabled advanced electrode architecture design." Carbon Energy 3, no. 3 (May 5, 2021): 424–39. http://dx.doi.org/10.1002/cey2.114.

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Abdallah, Yomna K., and Alberto T. Estévez. "3D-Printed Biodigital Clay Bricks." Biomimetics 6, no. 4 (October 7, 2021): 59. http://dx.doi.org/10.3390/biomimetics6040059.

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Construction materials and techniques have witnessed major advancements due to the application of digital tools in the design and fabrication processes, leading to a wide array of possibilities, especially in additive digital manufacturing tools and 3D printing techniques, scales, and materials. However, possibilities carry responsibilities with them and raise the question of the sustainability of 3D printing applications in the built environment in terms of material consumption and construction processes: how should one use digital design and 3D printing to achieve minimum material use, minimum production processes, and optimized application in the built environment? In this work, we propose an optimized formal design of “Biodigital Barcelona Clay Bricks” to achieve sustainability in the use of materials. These were achieved by using a bottom-up methodology of biolearning to extract the formal grammar of the bricks that is suitable for their various applications in the built environment as building units, thereby realizing the concept of formal physiology, as well as employing the concept of fractality or pixilation by using 3D printing to create the bricks as building units on an architectural scale. This enables the adoption of this method as an alternative construction procedure instead of conventional clay brick and full-scale 3D printing of architecture on a wider and more democratic scale, avoiding the high costs of 3D printing machines and lengthy processes of the one-step, 3D-printed, full-scale architecture, while also guaranteeing minimum material consumption and maximum forma–function coherency. The “Biodigital Barcelona Clay Bricks” were developed using Rhinoceros 3D and Grasshopper 3D + Plugins (Anemone and Kangaroo) and were 3D printed in clay.
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Allouzi, Rawan, Wael Al-Azhari, and Rabab Allouzi. "Conventional Construction and 3D Printing: A Comparison Study on Material Cost in Jordan." Journal of Engineering 2020 (May 1, 2020): 1–14. http://dx.doi.org/10.1155/2020/1424682.

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Three-dimensional (3D) printing is a procedure used to create 3D objects in which consecutive layers of a material are computer-controlled produced. Such objects can be constructed in any shape using digital model data. First, this paper presents a state-of-the-art review of the advances in 3D printing processes of construction. Then, the architectural, economical, environmental, and structural features of 3D printing are introduced. Examples of 3D printed structures are presented, and the construction challenges facing Jordan, that encouraged this study, are stated. Finally, a precise description regarding the impact of 3D printing is provided by comparing conventional construction data of Ras Alain Multipurpose Hall in Jordan and the expected data if the same building has been built using 3D printing. The suggested model is generated using Revit software. As a result of this study, an understanding of 3D printing procedure, mechanism of action, and its impact on the future of construction and architecture through economical, structural, and environmental parameters is achieved. This leads to encourage engineers and contractors to take this subject into account for construction in Jordan.
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Hansmeyer, Michael, and Benjamin Dillenburger. "Digital grotesque: Towards a micro-tectonic architecture." SAJ - Serbian Architectural Journal 5, no. 2 (2013): 194–201. http://dx.doi.org/10.5937/saj1302194h.

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Computational design allows for architecture with an extraordinary degree of topographical and topological complexity. Limitations of traditional CNC technologies have until recently precluded this architecture from being fabricated. While additive manufacturing has made it possible to materialize these complex forms, this has occurred only at a very small scale. In trying to apply additive manufacturing to the construction of full-scale architecture, one encounters a dilemma: existing large-scale 3D printing methods can only print highly simplified shapes with rough details, while existing high-resolution technologies have limited print spaces, high costs, or material attributes that preclude a structural use. This paper provides a brief background on additive manufacturing technology and presents recent developments in sand-printing technology that overcome current 3D printing restrictions. It then presents a specific experiment, Digital Grotesque project, which is the first application of 3D sand-printing technology at an architecture scale. It describes how this project attempts to exploit the potentials of these new technologies.
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Dissertations / Theses on the topic "3D printing architecture"

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Blakeway, Adam M. "Experiments with 3D printing technologies in masonry construction." Thesis, Massachusetts Institute of Technology, 2014. http://hdl.handle.net/1721.1/103493.

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Thesis: S.B., Massachusetts Institute of Technology, Department of Architecture, February 2016.
Cataloged from PDF version of thesis. "June 2014."
Includes bibliographical references (page 34).
Modern masonry construction finds itself in a cyclical pattern of "more of the same," insisting on standardized, basic designs consisting of little more than uniform stones laid in regular courses, which do little to add to the variability of the modem world. While these forms attain a surety in structural stability, they offer little in the form of variable aesthetics. 3D-printing, consistently hailed as one of the most promising developments of the 21 " century, allowing individuals from every walk of life to create and produce in real time, has, contrarily, failed to grasp our greater aspirations in the field of Architecture. Most attempts at the incorporation of 3D-printing technology in Architecture have simply been to scale the technologies to print larger and larger objects, eventually working up to entire buildings. While these efforts are beneficial in some ways, they consist of numerous drawbacks which make these types of strategies ultimately implausible, at least for the moment. Modern construction, once thought to be secure in its standards of structure and implementation, is now being challenged to develop designs far more elaborate than their "glass tower" counterparts by pushing the boundaries of what architectural moves are possible. The long held beliefs that stone must be orthogonal and uniform to be utilized in large-scale construction projects are being revamped in the wake of the 3D printing boom. This thesis seeks to find a synthesis between these two methods of modern construction, unifying the versatility and variability of 3D-printing and the stability and natural aesthetic of masonry, to create viable and aesthetically appealing architectural forms for the 2 1st century.
by Adam M. Blakeway.
S.B.
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Kim, Kyungsik M. Arch Massachusetts Institute of Technology. "Printing the vernacular : 3D printing technology and its impact on the City of Sana'a, Yemen." Thesis, Massachusetts Institute of Technology, 2016. http://hdl.handle.net/1721.1/103469.

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Thesis: M. Arch., Massachusetts Institute of Technology, Department of Architecture, 2016.
Cataloged from PDF version of thesis.
Includes bibliographical references (page 121).
This thesis project is a speculative proposal; it assumes that 3D printing technology is a major manufacturing and construction method in the future. The industrial revolution that has begun in the 19th century was the transition to a new manufacturing process. This transition included going from hand production to machine production and eventually changed the entire way of making things, buying things, moving things, and etc. The changes of our life led to the transformation of our cities. Current cities were formed based on the Industrial Supply Chain that enables flow of materials and products from supplier to customer. This supply chain decided locations of factories, retails, roads, ports, warehouses, and etc that have structured cities. In recent years, 3D printing has attracted increasing attention. The prospect of printing machines has inspired enthusiasts to proclaim that 3D printing will bring "the next industrial revolution", while others have reacted with skepticism and point to the technology's current limitations. However, 3D printing could proliferate rapidly over the coming decade. Improvements in speed and performance could enable unprecedented levels of mass customization, simplified supply chains, and even the "democratization" of manufacturing as consumers begin to print their own products. Although there has been a number of studies on the 3D Printing technology itself and its impact on economy, less attentions have been paid to its spatial impact or impact on our cities. As the industrial revolution transformed cities, 3D Printing is expected to change our current cities in many ways, as it will change the way of making, moving, buying things again. The fact that 3D Printing can be done near the point of consumption, implies several possible scenarios of future cities This thesis illustrates different degrees of influence of the technology in the city of Sana'a, Yemen. The city has four distinct areas currently: the historical world heritage site, a partially protected area, a modernized area, and an informal settlement. The four distinct areas will be changed in different ways by different uses of 3D printing technology. The tower house, which is one of the most significant building typologies of the city, is used to examine and compare the influences of the technology. More specifically, the ornament of the tower house and possible scenarios of transformation are the main design focus of the project. Ornament will appear in different scales and configurations in the future city of Sana'a, from high resolution ornament to inhabitable ornament.
by Kyungsik Kim.
M. Arch.
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Peng, Bangan. "FUNCTIONAL 4D PRINTING BY 3D PRINTING SHAPE MEMORYPOLYMERS VIA MOLECULAR, MORPHOLOGICAL AND GEOMETRICALDESIGNS." University of Akron / OhioLINK, 2020. http://rave.ohiolink.edu/etdc/view?acc_num=akron1605873309517501.

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Campbell, Andrew S. "Recycled Aggregate & Robotic Contour Crafting." University of Cincinnati / OhioLINK, 2019. http://rave.ohiolink.edu/etdc/view?acc_num=ucin1554119761226049.

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Macias, Diego. "Topological (Bio)Timber: An Algorithm and Data Approach to 3d Printing a Bioplastic and Wood Architecture." University of Cincinnati / OhioLINK, 2017. http://rave.ohiolink.edu/etdc/view?acc_num=ucin1491305462260965.

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Lundberg, Rasmus. "Kontextuell helhet av 3D-printad träullsandwich - Från prefab till printning in-situ." Thesis, KTH, Arkitektur, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-273734.

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Projektet syftar till att föreslå en rimlig riktning för hur additiva produktionsmetoder, alltså tillverkningsmetoder som använder lager-på-lager-teknik, kan tänkas påverka arkitekturen, att försöka sätta sig in i teknikerna och komma fram till vilken riktning som upplevs mest givande eller gångbar. Hur ska man nyttja potentialen med den nya tekniken på ett bra sätt? Jag har försökt ta fram en produkt som nyttjar potentialen hos de additiva produktionsmetoderna och som upplevs tänkbar för fullskalig realisering i byggsektorn i en närliggande framtid. Produkten består av en metod för framställning av en sandwichkonstruktion med hög trähalt och troligen lång livslängd. Metoden minskar byggsektorns klimatbelastning och kan ge stora rumsliga kvaliteter och formgivningsmöjligheter. Jag har genom fysiska experiment och utforskande av olika digitala fabrikationsmetoder försökt att visualisera och identifiera möjligheter med dessa nya tekniska hjälpmedel. Genom praktiska tester har jag prövat mina föreställningar av hur dessa metoder kan användas på effektiva sätt. Projektet vidga-des från att initialt omfatta additiva produktionsmetoder till att senare under tillämpningsfasen även omfatta digitala hjälpmedel såsom fotogrammetri och verktyg för parametrisk design. Projektet har resulterat i ett tillvägagångsätt för printning av cellulosabaserade sandwichkonstruktioner i printade formverk av återvinningsbar biokomposit.
The project aims to propose a direction for how additive manufacturing methods can influence architecture, to study the techniques and find out which direction could be perceived as most rewarding or viable. How to use the potential of the new technology in a good way? I have tried to develop a product that utilizes the potential of the additive manufacturing methods and which is conceivable for full-scale realization in the construction sector in the near future. The product consists of a method for producing long lasting sandwich constructions with high wood content. The method reduces the building industry's climate impact and can provide great spatial qualities and design possibilities. Through physical experiments and exploration of various digital fabrication methods, I have tried to visualize and identify possibilities with these new technological aids. Through practical tests, I have tested my ideas of how these methods can be used effectively. The project was expanded from initially studying additive production methods to, later during the application phase, also include digital aids such as photogrammetry and tools for parametric design. The project has resulted in a strategy for printing cellulose-based sandwich constructions in printed molds of recyclable biocomposite.
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Ramstedt, Clayton D. "Modular 3D Printer System Software For Research Environments." BYU ScholarsArchive, 2020. https://scholarsarchive.byu.edu/etd/8688.

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The Nordin group at Brigham Young University has been focused on developing 3D printing technology for fabrication of lab-on-a-chip (microfluidic) devices since 2013. As we showed in 2015, commercial 3D printers and resins have not been developed to meet the highly specialized needs of microfluidic device fabrication. We have therefore created custom 3D printers and resins specifically designed to meet these needs. As part of this development process, ad hoc 3D printer control software has been developed. However, the software is difficult to modify and maintain to support the numerous experimental iterations of hardware used in our custom 3D printers. This highlights the need for modular yet reliable system software that is easy to use, learn, and work with to adapt to the unique challenges of a student workforce. This thesis details the design and implementation of new 3D printer system software that meets these needs. In particular, a software engineering principle-based design approach is taken that lends itself to several specific development patterns that permit easy incorporation of new hardware into a 3D printer to enable rapid evaluation of and development with such new hardware.
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Almerbati, Nehal. "Hybrid heritage : an investigation into the viability of 3D-printed Mashrabiya window screens for Bahraini dwellings." Thesis, De Montfort University, 2016. http://hdl.handle.net/2086/12482.

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Current debates on design and manufacturing support the claim that the ‘Third Industrial Revolution’ has already started due to Additive Manufacturing (AM) and 3D Printing. The process of solidifying liquid or powder using a binding agent or a melting laser can save time and transportation costs associated with importing primary material if locally sourced material is available. This research investigates a framework approach, titled SAFE, for discussing the functionality, economic viability, production feasibility, and aesthetic and cultural value lent by 3D printing on an architectural scale through a construction known as a Mashrabiya. This traditional window screen has distinguished aesthetic, cultural yet functional constraints, and there is a manufacturing gap in the market that makes it a viable product option to be 3D printed. The practical element and design process related to reviving this screen are examined, from complex geometry development to cost and fabrication estimations. 3D printing technologies potentially offer solutions to solve issues in construction and assembly times, reduce labour costs, and address the loss of hand craft making skills in a variety of cultures, typically Middle Eastern ones; this was a factor in the abandonment of old Mashrabiya in houses typified with Bahrain as a case. Presently, there is a growing wealth of literature that highlights not only the strength of Mashrabiya as a design concept but also as a possible 3D printed product. Interviews with a total of 42 local Bahraini manufacturers, academics and architects as well as 4 case studies and 2 surveys and 11 focus groups are hybrid mixed methods used to define a new 3D printed Mashrabiya (3DPM) prototype. The future of the 3D Mashrabiya prototype is further supported by economic forecasts, market research, and interviews with global manufacturers and 3D printing designers’ insights into the subject in an accretive design process. The research contributes to an understanding of the implications of technologies that enable mass customisation in the field of 3D-printed architecture in general and in the Bahraini market in particular. The process for developing a prototype screen and in determining its current economic value will prove significant in predicting the future benefits and obstacles of 3D-printed large scale architectural products in the coming five years as advised by industry experts. The main outcomes relate to establishing boundaries determining the validity of using 3D printing and a SAFE framework to produce a parametric Mashrabiya and other similar heritage architectural archetypes. This can be used to enhance the globalism of the design of Middle Eastern dwellings and to revive social identity and cultural traditions through innovative and reasonable yet superior design solutions using a hybrid architectural design language.
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Гордюк, Іван Васильович, Ivan Vasilyevich Gordyuk, Анжела Борисівна Зузяк, and Angela Borisivna Zuziak. "Особливості використання технології 3D-друку в будівництві." Thesis, Національний авіаційний університет, 2018. http://er.nau.edu.ua/handle/NAU/37949.

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Sengeh, David Moinina. "Advanced prototyping of variable impedance prosthetic sockets for trans-tibial amputees : polyjet matrix 3D printing of comfortable prosthetic sockets using digital anatomical data." Thesis, Massachusetts Institute of Technology, 2012. http://hdl.handle.net/1721.1/76573.

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Thesis (S.M.)--Massachusetts Institute of Technology, School of Architecture and Planning, Program in Media Arts and Sciences, 2012.
Cataloged from PDF version of thesis.
Includes bibliographical references (p. 66-68).
This work, supported by the Media Lab Consortium, evaluates the design of a Variable Impedance Prosthetic (VIPr) socket for a transtibial amputee using computer-aided design and manufacturing (CAD/CAM). Compliant features are seamlessly integrated into a 3D printed socket to achieve lower interface peak pressures over bony protuberances by using anthropomorphic data acquired through surface scanning and magnetic resonance imaging techniques. An inverse linear mathematical transformation spatially maps quantitative measurements (bone tissue depth) of the human residual limb to the corresponding socket shape and impedance characteristics. The CAD/CAM VIPr socket is compared to a state-of-the-art prosthetic socket of similar internal geometry and shape, designed by a prosthetist using conventional methods. An active, bilateral transtibial male amputee of weight 70 kg walks on a force plate loaded 5-meter walkway, at self-selected speeds while synchronized ground reaction forces, motion capture data and socket residual limb interface pressures are measured for the evaluated sockets. We anticipated a decreased average interface pressure (measured using the Teksan F-SocketTM pressure sensors) in the VIPr socket, especially over stiff anatomical landmarks including the fibula head, the tibia, lateral and medial femoral condyles and medial tibial flare. Contact interface pressure recorded during stance of a complete gait cycle indicated a 15% and 17% reduction at toe-off and heel-strike respectively at the fibula head while the subject uses a VIPr socket in comparison to a conventional socket of similar internal shape. A corresponding 7% and 8% reduction in pressure is observed along the tibia. Similar trends of high-pressure reductions are observed during stair ascent trials with the VIPr socket.
by David Moinina Sengeh.
S.M.
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Books on the topic "3D printing architecture"

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BAÑÓN, Carlos, and Félix RASPALL. 3D Printing Architecture. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-15-8388-9.

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author, San Fratello Virginia, ed. Printing architecture: Innovative recipes for 3D printing. Princeton Architectural Press, 2018.

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Fratello, Virginia San, and Ronald Rael. Printing Architecture: Innovative Recipes for 3D Printing. Princeton Architectural Press, 2018.

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Leach, Neil, and Behnaz Farahi. 3D-Printed Body Architecture. Wiley & Sons, Incorporated, John, 2017.

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3D-Printed Body Architecture. Wiley & Sons, Incorporated, John, 2018.

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Leach, Neil, and Behnaz Farahi. 3D-Printed Body Architecture. Wiley & Sons, Incorporated, John, 2018.

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Leach, Neil, and Behnaz Farahi. 3D-Printed Body Architecture. Wiley & Sons, Limited, John, 2017.

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BAÑÓN, Carlos, and Félix RASPALL. 3D Printing Architecture: Workflows, Applications, and Trends. Springer Singapore Pte. Limited, 2020.

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Press, Keep It Simple. Isometric Grid Paper: 6x9 for Quilt Pattern Planning, Architecture, 3D Printing, Landscaping. Independently Published, 2019.

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PRESS, KEEP IT SIMPLE. ISOMETRIC GRID PAPER: 7x10 for quilt pattern planning, architecture, 3D printing, landscaping. Independently published, 2019.

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Book chapters on the topic "3D printing architecture"

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Fratello, Virginia San. "3D Printing Architecture." In TMS 2021 150th Annual Meeting & Exhibition Supplemental Proceedings, 37–49. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-65261-6_4.

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López, Mercedes Valiente, M. Carmen Sanz Contreras, and J. Ramon Osanz Díaz. "3D Printing in Presentation Architecture Projects." In Putting Tradition into Practice: Heritage, Place and Design, 636–44. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-57937-5_66.

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Molina-Siles, Pedro, Francisco Javier Cortina Maruenda, Hugo Barros Costa, and Salvador Gilabert Sanz. "3D Printing as a Technological Tool Geared Towards Architecture." In Architectural Draughtsmanship, 1063–73. Cham: Springer International Publishing, 2017. http://dx.doi.org/10.1007/978-3-319-58856-8_84.

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Thomsen, Mette Ramsgaard, Martin Tamke, Aurelie Mosse, Jakob Sieder-Semlitsch, Hanae Bradshaw, Emil Fabritius Buchwald, and Maria Mosshammer. "Imprimer La Lumiere – 3D Printing Bioluminescence for Architectural Materiality." In Proceedings of the 2021 DigitalFUTURES, 305–15. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-16-5983-6_28.

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Abstract‘Imprimer la Lumière’ examines the making of a bioluminescent micro architecture. The project positions itself inside a sustainability agenda. By exploring the use of light-emitting bacteria as a material for architecture it asks what are the concepts, methods and technologies needed for designing with living materials. The project devises new means by which to design with the luminescent vibrio fischeri bacteria in a 3D printing manufacturing process based on extrusion principles. By combining the study of these living organisms and their appropriation through advanced robot-controlled 3D printing technologies, we establish a conceptual, material and technological framework for a bio-controlled bacteria growth and 3D extrusion process and a printable material based on agarose and gelatine.
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Mohamed, H., D. W. Bao, and R. Snooks. "Super Composite: Carbon Fibre Infused 3D Printed Tectonics." In Proceedings of the 2020 DigitalFUTURES, 297–308. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-33-4400-6_28.

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AbstractThis research posits an innovative process of embedding carbon fibre as the primary structure within large-scale polymer 3D printed intricate architectural forms. The design and technical implications of this research are explored and demonstrated through two proto-architectural projects, Cloud Affects and Unclear Cloud, developed by the RMIT Architecture Snooks Research Lab. These projects are designed through a tectonic approach that we describe as a super composite – an approach that creates a compression of tectonics through algorithmic self-organisation and advanced manufacturing. Framed within a critical view of the lineage of polymer 3D printing and high tech fibres in the field of architectural design, the research outlines the limitations of existing robotic processes employed in contemporary carbon fibre fabrication. In response, the paper proposes an approach we describe as Infused Fibre Reinforced Plastic (IFRP) as a novel fabrication method for intricate geometries. This method involves 3D printing of sacrificial formwork conduits within the skin of complex architectural forms that are infused with continuous carbon fibre structural elements. Through detailed observation and critical review of Cloud Affects and Unclear Cloud (Fig. 2), the paper assesses innovations and challenges of this research in areas including printing, detailing, structural analysis and FEA modelling. The paper notes how these techniques have been refined through the iterative design of the two projects, including the development of fibre distribution mapping to optimise the structural performance.
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Rosendahl, P. L., and A. Wolf. "The business case for 3D printing in the built environment." In Structures and Architecture A Viable Urban Perspective?, 254–59. London: CRC Press, 2022. http://dx.doi.org/10.1201/9781003023555-31.

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Ko, Minjae, Donghan Shin, Hyunguk Ahn, and Hyungwoo Park. "InFormed Ceramics: Multi-axis Clay 3D Printing on Freeform Molds." In Robotic Fabrication in Architecture, Art and Design 2018, 297–308. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-92294-2_23.

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Eti Proto, Meltem, and Ceren Koç Sağlam. "Furniture Design Education with 3D Printing Technology." In Makers at School, Educational Robotics and Innovative Learning Environments, 97–105. Cham: Springer International Publishing, 2021. http://dx.doi.org/10.1007/978-3-030-77040-2_13.

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AbstractThree-dimensional printing technology has an important place in furniture and interior design, a strong global sector that responds rapidly to the changing needs and expectations of the individual and society. The main objective of design education should be to equip us to imagine new models of life. Among the most attractive benefits of 3D printing technology that make it a boon to designers working in the building and furniture sector are that it enables them to seek original forms that cannot be produced in molds, it generates less waste, and is accessible to all. Today, innovation in the profession, innovative materials, and knowledge of innovative production technologies that feed creative thinking have become ever important features of design education. This knowledge will allow us to imagine, discuss and pioneer design production ideas for new life models. This paper discusses 3D printing technology, the furniture design studio method and its contribution to design education in the Production Techniques courses of the Interior Architecture Department of Marmara University’s Faculty of Fine Arts led by Professor Meltem Eti Proto, Instructor Can Onart, Lecturer T. Emre Eke, and Research Assistant Ceren Koç Sağlam.
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Battaglia, Christopher A., Martin Fields Miller, and Sasa Zivkovic. "Sub-Additive 3D Printing of Optimized Double Curved Concrete Lattice Structures." In Robotic Fabrication in Architecture, Art and Design 2018, 242–55. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-92294-2_19.

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Beyhan, Figen, and Semra Arslan Selçuk. "3D Printing in Architecture: One Step Closer to a Sustainable Built Environment." In Lecture Notes in Civil Engineering, 253–68. Cham: Springer International Publishing, 2018. http://dx.doi.org/10.1007/978-3-319-63709-9_20.

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Conference papers on the topic "3D printing architecture"

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Zhan, Qiang, Hao Wu, Liming Zhang, Philip F. Yuan, and Tianyi Gao. "3D Concrete Printing with Variable Width Filament." In eCAADe 2021: Towards a New, Configurable Architecture. eCAADe, 2021. http://dx.doi.org/10.52842/conf.ecaade.2021.2.153.

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Marijnissen, Marjolein P. A. M., and Aant van der Zee. "3D Concrete Printing in Architecture - A research on the potential benefits of 3D Concrete Printing in Architecture." In eCAADe 2017 : ShoCK! – Sharing of Computable Knowledge! eCAADe, 2017. http://dx.doi.org/10.52842/conf.ecaade.2017.2.299.

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Marijnissen, Marjolein P. A. M., and Aant van der Zee. "3D Concrete Printing in Architecture - A research on the potential benefits of 3D Concrete Printing in Architecture." In eCAADe 2017 : ShoCK! – Sharing of Computable Knowledge! eCAADe, 2017. http://dx.doi.org/10.52842/conf.ecaade.2017.2.299.

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Hennessey, Michael P., Alex J. Beaulier, and Cheri Shakiban. "Modeling and 3D Printing of Ruled Surfaces." In ASME 2015 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2015. http://dx.doi.org/10.1115/detc2015-46494.

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Ruled surfaces play an important role in disciplines such as applied mathematics, mechanical engineering, and architecture. We present a general methodology for creating handheld-sized 3D printed models of such surfaces, which can be useful for educational, research, and design purposes. The process begins with a mathematical description of the surface, either by means of establishing a series of line segment endpoint coordinates followed by a “connect the dots” approach or continuously sweeping a portion of a line throughout 3D space using a time-varying homogeneous transformation, thereby defining an array of line segments on the surface. Next, MATLAB is used to numerically generate the endpoint coordinates which are imported into SolidWorks via Excel and employs a custom macro to permit graphical display of the line segments in a part file. The array of line segments is then stitched together “manually” into a surface, thickened into a part, and printed out in plastic using a 3D printer. The methodology is illustrated for some simple surfaces in addition to several well-known exotic surfaces that have an architectural theme to them. Specifically, we showcase Antoni Gaudi’s conoids and elliptic hyperboloids from La Sagrada Familia, in addition to a twisted circular drum arch and a Solomonic column, both of which are seen in southern European architecture, in particular they are present at either the Museum of Cycladic Art in Athens or at The Vatican (includes museum). In summary, the work presented should be of general interest to the 3D printing, ruled surface, and architecture communities.
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Chen, Dechen, Dan Luo, Weiguo Xu, Chen Luo, Liren Shen, Xia Yan, and Tianjun Wang. "Re-perceive 3D printing with Artificial Intelligence." In eCAADe 2019: Architecture in the Age of the 4th Industrial Revolution. eCAADe, 2019. http://dx.doi.org/10.52842/conf.ecaade.2019.1.443.

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Dunn, Kate, Hank Haeusler, Yannis Zavoleas, Mel Bishop, Katherine Dafforn, Francisco Sedano, Daniel Yu, and Nina Schaefer. "Recycled Sustainable 3D Printing Materials for Marine Environments." In eCAADe 2019: Architecture in the Age of the 4th Industrial Revolution. eCAADe, 2019. http://dx.doi.org/10.52842/conf.ecaade.2019.2.583.

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Dunn, Kate, Hank Haeusler, Yannis Zavoleas, Mel Bishop, Katherine Dafforn, Francisco Sedano, Daniel Yu, and Nina Schaefer. "Recycled Sustainable 3D Printing Materials for Marine Environments." In eCAADe 2019: Architecture in the Age of the 4th Industrial Revolution. eCAADe, 2019. http://dx.doi.org/10.52842/conf.ecaade.2019.2.583.

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Cavaliere, Ilaria, Angelo Vito Graziano, and Dario Costantino. "STEREOTOMIC GREEN VAULT: CLAY 3D PRINTING APPLIED TO STEREOTOMY." In DARCH 2022 November - 3rd International Conference on Architecture & Design. International Organization Center of Academic Research, 2022. http://dx.doi.org/10.46529/darch.202234.

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Ren, Lei, Shicheng Wang, Yijun Shen, Shikai Hong, Yudi Chen, and Lin Zhang. "3D Printing in Cloud Manufacturing: Model and Platform Design." In ASME 2016 11th International Manufacturing Science and Engineering Conference. American Society of Mechanical Engineers, 2016. http://dx.doi.org/10.1115/msec2016-8669.

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Although 3D printing has attracted remarkable attention from both industry and academia society, still only a relatively small number of people have access to required 3D printers and know how to use them. One of the challenges is that how to fill the gap between the unbalanced supply of various 3D printing capabilities and the customized demands from geographically distributed customers. The integration of 3D printing into cloud manufacturing may promote the development of future smart networks of virtual 3D printing cloud, and allow a new service-oriented 3D printing business model to achieve mass customization. This paper presents a primary 3D printing cloud model and an advanced 3D printing cloud model, and analyzes the 3D printing service delivery paradigms in the models. Further, the paper proposes a 3D printing cloud platform architecture design to support the advanced model. The proposed advanced 3D printing cloud model as well as the architecture design can provide a reference for the development of various 3D printing clouds.
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"3D-Printing, Topology Optimization and Statistical Learning: A Case Study." In 2017 Symposium on Simulation for Architecture and Urban Design. Society for Modeling and Simulation International (SCS), 2017. http://dx.doi.org/10.22360/simaud.2017.simaud.012.

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Reports on the topic "3D printing architecture"

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Williams, Michelle. Geomechanical Characterization of Geo-architectured Rock Specimens Using Gypsum-based 3D Printing. Office of Scientific and Technical Information (OSTI), December 2019. http://dx.doi.org/10.2172/1592887.

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Vavrin, John L., Ghassan K. Al-Chaar, Eric L. Kreiger, Michael P. Case, Brandy N. Diggs, Richard J. Liesen, Justine Yu, et al. Automated Construction of Expeditionary Structures (ACES) : Energy Modeling. Engineer Research and Development Center (U.S.), February 2021. http://dx.doi.org/10.21079/11681/39641.

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The need to conduct complex operations over time results in U.S. forces remaining in deployed locations for long periods. In such cases, more sustainable facilities are required to better accommodate and protect forward deployed forces. Current efforts to develop safer, more sustainable operating facilities for contingency bases involve construction activities that redesign the types and characteris-tics of the structures constructed, reduce the resources required to build, and reduce resources needed to operate and maintain the com-pleted facilities. The Automated Construction of Expeditionary Structures (ACES) project was undertaken to develop the capability to “print” custom-designed expeditionary structures on demand, in the field, using locally available materials with the minimum number of personnel. This work investigated large-scale automated “additive construction” (i.e., 3D printing with concrete) for construction applications. This document, which documents ACES energy and modeling, is one of four technical reports, each of which details a major area of the ACES research project, its research processes, and associated results, including: System Requirements, Construction, and Performance; Energy and Modeling; Materials and Testing; Architectural and Structural Analysis.
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Diggs, Brandy N., Richard J. Liesen, Michael P. Case, Sameer Hamoush, and Ahmed C. Megri. Automated Construction of Expeditionary Structures (ACES) : Energy Modeling. Engineer Research and Development Center (U.S.), February 2021. http://dx.doi.org/10.21079/11681/39759.

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The need to conduct complex operations over time results in U.S. forces remaining in deployed locations for long periods. In such cases, more sustainable facilities are required to better accommodate and protect forward deployed forces. Current efforts to develop safer, more sustainable operating facilities for contingency bases involve construction activities that redesign the types and characteris-tics of the structures constructed, reduce the resources required to build, and reduce resources needed to operate and maintain the com-pleted facilities. The Automated Construction of Expeditionary Structures (ACES) project was undertaken to develop the capability to “print” custom-designed expeditionary structures on demand, in the field, using locally available materials with the minimum number of personnel. This work investigated large-scale automated “additive construction” (i.e., 3D printing with concrete) for construction applications. This document, which documents ACES energy and modeling, is one of four technical reports, each of which details a major area of the ACES research project, its research processes, and associated results, including: System Requirements, Construction, and Performance; Energy and Modeling; Materials and Testing; Architectural and Structural Analysis.
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Al-Chaar, Ghassan K., Peter B. Stynoski, Todd S. Rushing, Lynette A. Barna, Jedadiah F. Burroughs, John L. Vavrin, and Michael P. Case. Automated Construction of Expeditionary Structures (ACES) : Materials and Testing. Engineer Research and Development Center (U.S.), February 2021. http://dx.doi.org/10.21079/11681/39721.

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Complex military operations often result in U.S. forces remaining at deployed locations for long periods. In such cases, more sustaina-ble facilities are required to better accommodate and protect forward-deployed forces. Current efforts to develop safer, more sustaina-ble operating facilities for contingency bases involve construction activities that require a redesign of the types and characteristics of the structures constructed, that reduce the resources required to build, and that decrease the resources needed to operate and maintain the completed facilities. The Automated Construction of Expeditionary Structures (ACES) project was undertaken to develop the capa-bility to “print” custom-designed expeditionary structures on demand, in the field, using locally available materials with the minimum number of personnel. This work investigated large-scale automated “additive construction” (i.e., 3D printing with concrete) for con-struction applications. This report, which documents ACES materials and testing, is one of four technical reports, each of which details a major area of the ACES research project, its research processes, and its associated results. There major areas include System Require-ments, Construction, and Performance; Energy and Modeling; Materials and Testing; Architectural and Structural Analysis.
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