Spelling suggestions: "subject:"three dimensional printing"" "subject:"three dimensional aprinting""
31 |
Evaluation of a Patient-Specific, Low-Cost, 3-Dimensional–Printed Transesophageal Echocardiography Human Heart PhantomMeineri, Massimiliano 02 November 2021 (has links)
Simulation based education has been shown to increase the task-specific capability of medical trainees. Transesophageal echocardiography training greatly benefits from the use of simulators. They allow real time scanning of a beating heart and generation of ultrasound images side by side with anatomically accurate virtual model. These simulators are costly and have many limitations. 3D printing technologies have enabled the creation of bespoke phantoms capable of being used as task-trainers. This study aims to compare the ease of use and accuracy of a low-cost patient-specific, Computer-tomography based, 3D printed, echogenic TEE phantom compared to a commercially available echocardiography training mannequin.
We hypothesized that a low-cost, 3D printed custom-made, cardiac phantom has comparable image quality, accuracy and usability as existing commercially available echocardiographic phantoms.
After Institutional Ethic Research Board approval, we recruited ten American Board – Certified cardiac anesthesiologists and conducted a blinded comparative study divided into two stages. Stage one consisted of image assessment. A set of basic TEE views obtained from the 3D printed and commercial phantom were presented to the participants on a computer screen in random order. For each image, participants will be asked to identify the view, identify the quality of the image on a 1-5 Likert scale compared to the corresponding human view and guess with which phantom it was acquired (1 not at all realistic to patients view and 5 realistic to patients view). Stage two, participants will be asked to use the 3D printed and the commercially available phantom to obtain basic TEE views. In a maximum of 30 minutes. Each view was recorded and assessed for accuracy by two certified echocardiographers. Time needed to acquire each basic view and number of correct views was recorded. Overall usability of the phantoms was assessed through a questionnaire. For all continuous variables, we will calculate mean, median and standard deviation. We use Wilcoxon Signed-Rank test to assess significant differences in the rating of each phantom.
All ten participants completed all part of the study. All participants could recognize all of the standard views. The average Likert scale was 3.2 for the 3D printed and 2.9 for the commercial Phantom with no significant difference. The average time to obtain views was 24.5 and 30 sec for the 3D printed and the commercial phantoms respectively statistically significantly in favor of the 3D printed phantom. The qualitative user assessment for ease to obtain the views, probe manipulation, image quality and overall experience were in great favor of the 3D printed phantom.
Our Study suggest that the quality of TEE images obtained on the 3D printed phantom are not significantly different from those obtained on the commercial Phantom. The ease of use and time required to complete a basic TEE exam were in favor of the 3D Printed phantom.:Table of Content
1. Bibliographic Description 3
2. Introduction 4
2.1. Perioperative transesophageal echocardiography 4
2.2. Transesophageal echocardiography training 5
2.3. Transesophageal echocardiography simulation 6
2.4. 3D Heart Printing 13
2.5. 3D Segmentation 16
2.6. Development of the study phantom 17
2.7. Study Rationale 18
3. Publication 22
4. Summary 30
5. References 33
6. Appendices 37
6.1. Darstellung des eigenes Beitrags 38
6.2. Erklärung über die eigenständige Abfassung der Arbeit 39
6.3. Lebenslauf 40
6.4. Publikationen und Vorträge 44
6.5. Danksagung 61
|
32 |
Analysis of accuracy and mechanical properties of 3D-printed polymeric dental materialsAlshaibani, Raghdah Mohammedali 28 May 2024 (has links)
OBJECTIVES: The objective was to investigate the accuracy, storage stability, and
mechanical properties of 3D-printed polymeric dental materials.
MATERIALS AND METHODS: Three completely dentate models, two maxillary and one
mandibular each with their respective die, and three implant models were designed using
dental CAD software (3SHAPE DENTAL SYSTEM). A horseshoe-shaped solid base with
a posterior horizontal bar was utilized. The models were printed based on the
manufacturer's instructions for four weeks using six printers with the corresponding
recommended resin materials: Carbon M2 (DPR10), HeyGears A2D4K (Model HP
UV2.0), Stratasys J5 (MED610), Stratasys Origin One (DM200), Envision One (E-Model
LightDLP), and Asiga Pro4K (VeriModel) with a standard layer thickness of 50 μm
(N=72). The models were scanned after printing using Sirona inEOS X5 scanner, while the implant models were scanned using a CT scanner (GE Phoenix V|tome|x metrology edition). The full arch models were randomly assigned to three groups of storage conditions: cold environment (LT, 4 ± 1°C), hot and dry environment (HT, 50 ± 2°C), and
room temperature (RT , 25 ± 2°C, serving as the control). Each group was kept under the
designated conditions and scanned at 1, 2, 3, 4, and 8 weeks. The generated STL files were
imported into a 3D inspection software for comparison with the original STL files. Four
sets of reference points (central fossa of first premolars and central fossae of second molars)
were selected to determine six distances of inter-arch segments, from which the inter-arch
distance trueness and precision deviation were measured.
For the second part of the study, maxillary Lucitone Digital Print denture base (DB) (N=5),
maxillary Lucitone IPN 3D Premium anterior and posterior teeth (N=6), and maxillary
Keystone Keysplint Soft Clear occlusal splint (N=5) were printed using two printers
(Carbon M2, Asiga Max UV) with a standard layer thickness of 50 μm for denture base
and teeth, and 100 μm for the occlusal splint. The tolerance threshold was set to 50 μm for
Lucitone IPN and 100 μm for Lucitone DB and Keysplint Soft. In-tolerance percentage
and deviation RMS were obtained and analyzed with multivariate least square mean linear
regression using JMP Pro 17 (SAS, Cary, NC) to identify significant effects (α=0.05).
The third part investigated the mechanical properties of Lucitone DB and IPN using 2
printers (Carbon M2, Asiga Max UV) as follows: flexural strength (N=10) using a threepoint
bend test, fracture toughness (N=10), creep (N=5), Vickers hardness test (N=15),
surface roughness (N=15), while Shore A hardness (N=15) and tensile strength (N=10)
were performed for Keysplint Soft Clear. Data were analyzed using one-way and multivariate least square mean linear regression followed by Tukey’s HSD test using JMP Pro 17 (SAS, Cary, NC) to identify significant effects (α=0.05).
RESULTS: The in-tolerance percentage varied significantly among printers, with Carbon M2
(CAB) showing the highest values. Stratasys (J5) displayed the highest accuracy in term of
precision, while HeyGears A2D4K (HGS), Carbon M2 (CAB), and Stratasys (J5) exhibited
the highest accuracy in term of trueness. The inter-molar segment showed the highest
deviation. No significant difference was observed in in-tolerance percentage across
different print weeks except for week 2 in one printer (Stratasys Origin1). CAB exhibited
a higher in-tolerance percentage for the DB than Asiga Max UV (ASG), with the fitting
surface having the highest in-tolerance percentage. IPN anterior teeth had a higher intolerance
percentage than posterior teeth, with ASG showing a higher value than CAB. No
statistically significant difference was found in the in-tolerance percentage of Keysplint
Soft Clear between ASG and CAB. Resin printed using ASG demonstrated higher flexural
strength, Vickers hardness, and creep, while resin printer using CAB exhibited higher
fracture toughness, with no significant difference in surface roughness between the two
printers. Lucitone IPN had higher flexural strength and Vickers hardness, surface
roughness , and lower creep and fracture toughness than Lucitone DB. CAB Keysplint
Soft had higher tensile strength than ASG, with no statistically significant difference in
Shore A hardness between the two printers.
CONCLUSION: Model dimension deviations were impacted by storage conditions and the
specific printer utilized, with high-temperature storage exhibiting the least stability.
However, no significant difference was noted between low and room temperature storage
conditions. Carbon M2 exhibited the highest level of accuracy. The of 3D-printed denture
bases and denture teeth varied across different printers. Conversely, no significant
difference in accuracy was observed for a soft occlusal splint between two printers.
Materials printed using different printers showed statistically significant different
mechanical properties.
|
33 |
Time-evolution of viscoelastic properties of fresh cement pastes with oscillatory shear techniques: methodology, microstructural understanding, and 3D printing applicationsBadjatya, Palash January 2024 (has links)
3D printing in construction offers significant advantages in cost, material, and time efficiency, but material-related challenges need to be overcome for accelerated adoption. One of these challenges is understanding the rheological properties of cement paste, the primary fluid component of concrete, and how they are related to its microstructure. Moreover, the change in these properties over time must be monitored as the paste is a dynamic system in the fresh state, the period most relevant for the 3D printing process. The dissertation primarily explores and emphasizes the viability of small amplitude oscillatory shear techniques for understanding and differentiating between the microstructural evolution of cement pastes without and with printability-enhancing additives.
Understanding the rheology of cement pastes, especially the time-evolution of viscoelastic properties, is crucial for 3D printing as they affect the flow of the material and structural stability throughout the printing process. Viscoelastic properties can be measured using oscillatory rheological experiments, which have been found suitable for cementitious materials and provide key properties like storage modulus and loss modulus, among others. There has been a growing interest in using such rheological techniques as there still exist many unanswered questions regarding rheological-microstructure and microstructure-printability relationships. The mixture of cement and water by itself is not printable; additives are generally required. Additives like nanoclays, calcium carbonate whiskers, and viscosity-modifying agents can enhance the printability of concrete by improving structural buildup and flow behavior. However, their microstructure-printability relationship remains unexplored, and this investigation has tried to shed some light on it. The dissertation is structured into chapters that discuss rheological measurements, the impact of additives, and various testing methods to support hypotheses about microstructure-rheology relationships and 3D printability.
Chapter 1 involved the use of small amplitude oscillatory sweep techniques to study ordinary Portland and Portland limestone cements. Yield stress and viscosity are commonly measured rheological properties for printability, but these tests may provide little information about the microstructure as they are destructive in nature. Oscillatory sweep tests can be non-destructive and provide information about the microstructure before structural breakdown, which is important for the material that is already extruded. This material is at rest but is also undergoing hydration, which necessitates monitoring the evolution of material properties over time. The relatively few studies that exist that have studied this time-evolution have focused primarily on the evolution of storage modulus, while the change in the critical strain parameter, which is itself important for measuring the storage modulus, has remained unexplored.
In this chapter, an ordinary Portland cement (OPC) and a Portland limestone cement (PLC), mixed at different w/c ratios, were subjected to amplitude sweeps to observe the time-evolution of critical strain during the induction period. A Python algorithm was developed for extracting several different rheological properties along with critical strain. As hydration progressed, critical strains were found to increase exponentially and had an inverse correlation with the w/c ratio. The increase was quantified by an equation with a good fit using w/c ratio and time as the dependent variables. It was also shown that critical strain and storage modulus have different growth profiles, which could mean that the underlying microstructural factors for those properties are different. It was also shown that the choice of criterium for locating critical strain significantly affected the calculated critical strain and highlighted the importance of standardization of such criteria.
Chapter 2 extended the application of the oscillatory techniques and hypotheses toward cement pastes with additives that could improve 3D printability. Chemical admixtures and mineral additives are generally added to cement-based materials to achieve adequate printability. This investigation employed additives with different physical and chemical properties to observe their impacts on printability and hydration kinetics. Amplitude sweeps were used to measure changes in various rheological properties during the dissolution and induction periods in plain and additive-modified pastes. This chapter shows that amplitude sweeps can be effective methods for differentiating between cement pastes with different additives. The chapter also showed the importance of monitoring properties other than critical strain and storage modulus, specifically the yielding strain, for facilitating an understanding of microstructure-rheological property relationships when combined with other characterization techniques. Establishing these relationships can eventually help explain why printability-enhancing additives that are already used are effective and can provide a tool to explore more additives in the future.
Chapter 3 explored the use of in-situ characterization tests to help support the claims made in previous chapters. pH testing on various cement pastes highlighted the correlation between pH and storage modulus. Electrical impedance measurements were conducted to monitor cement hydration and microstructural development. The resistance of the pastes increased over time, with an initial slow rate followed by a rapid exponential increase, correlating with critical strain. The pH and resistance results showed they could be promising in-situ measurement techniques for monitoring prints on-site. The chapter also includes a discussion on the properties of methylcellulose, specifically its foaming capability and polymeric behavior, which potentially affected the rheological results and printability.
Chapter 4 discussed the methodologies and results of frequency and time sweeps in rheological tests, focusing on the storage modulus. It examined how different factors, such as amplitude, frequency, and additives, affect continuous measurement. Amplitude and frequency sweeps are interconnected, requiring both to be performed in tandem to determine the best combination of amplitude and frequency for time sweep tests. Frequency sweeps on different cement pastes showed that storage modulus curves change over time, with smoother curves at different frequencies depending on the age of the paste. Additives affect the frequency sweep results, leading to different ranges of ideal frequencies and storage modulus values. Time sweeps were conducted by varying the oscillation amplitude and frequency, and it was found that varying them during the time sweep can improve the quality of storage modulus evolution curves. The results also suggested that the minimum strain rate required varies over time, and can be achieved by changing either the strain amplitude or the frequency. The chapter also included a preliminary investigation on structural rebuilding, which showed that all rheological properties that were monitored recovered fully, at a more rapid rate during rebuilding.
The results and hypotheses presented in Chapters 1, 2, and 4 can serve as foundations for improving measurement protocols for oscillatory tests and, combined with Chapter 3, can guide further explorations of viable techniques to study microstructure evolution during the induction period of cement pastes.
|
34 |
A technical and economical evaluation of RP technology for RTM toolingDippenaar, D. J. 03 1900 (has links)
Thesis (MScEng (Mechanical and Mechatronic Engineering))--University of Stellenbosch, 2010. / ENGLISH ABSTRACT: This project investigates the use of Rapid Prototyping (RP), with specific focus
on Three Dimensional Printing (3DP), in the manufacture of complex shaped advanced
composite parts, using variants of the Resin Transfer Moulding (RTM)
method of composite manufacture. This study developed design guidelines, cost
models and a process chain by studying data obtained by making example parts,
from literature and consultation with industry. Advanced composite materials offer
some of the best low weight and high specific strength properties for the solution
of design problems. A major disadvantage of these processes, however, is the
low production rates possible and the need of costly moulds. The 3DP technologies
combined with the RTM composite process was found to enable a lowering
of costs and increase in productivity if smaller batch sizes are considered. The
most meaningful area of application for RP techniques seems to be for smaller
and more complex components. The geometrical freedom allowed by RP technologies
allowed the manufacture of parts which are challenging to manufacture
by conventional technology such as CNC machining. Example part case studies
were completed for a simple part utilising the one sided mould Resin Infusion
RTM variant as well as for a complex part utilising the closed mould Vacuum Assisted
Resin Transfer Moulding (VARTM) process variant. During these two case
studies it was clear that proper part infusion with resin is critical for the manufacture
of good quality composite parts free of voids and dry spots. It is possible to
improve the resin infusion by correct placement of resin inlet and outlet ports as
well as resin channels incorporated in the mould. Correct placement of these features
for the case studies was obtained through simulations done with RTM-Worx
software. Results also indicated that another useful application of RP technology
to RTM is the manufacture of disposable cores for parts with thick cross sections.
Resin channels were included on the surface of these cores to improve the mould
filling with resin and consequently part quality. An early cost estimation model,
based on the work of Veldsman (1995), was developed for the combined RP and
RTM manufacturing process. This model may help designers to eliminate expensive
design features and enables a quick cost comparison with competing processes.
Drawbacks of applying RP techniques to RTM include the limited lifetime
of moulds produced with 3DP and the size and accuracy limitations of the RP
t echnology. / AFRIKAANSE OPSOMMING: Hierdie projek handel oor die toepassing van die drie-dimensionele druk metode
van Snel-Prototipering (Rapid Prototyping) op die vervaardiging van komplekse
gevorderde saamgestelde materiaal komponente met die Hars-Inspuit Giet
(Resin Transfer Moulding) metode. Die projek behels die opstel van ontwerpsriglyne,
koste-modelle en ’n proses-ketting deur data te bestudeer wat bekom
is deur middel van die vervaardiging van eksperimentele parte, literatuurstudie
asook raadpleging met individue in die industrie. Gevorderde
saamgestelde materiale verskaf van die beste sterk, dog ligte oplossings vir sekere
ontwerpsprobleme. ’n Ernstige nadeel van hierdie materiale is egter die stadige
produksietempo moontlik en die vereiste van duur gietstukke. Die Snel-
Prototipering metodes, gekombineerd met ’n saamgestelde materiaal vervaardigingsproses,
maak laer kostes met beter produktiwiteit moontlik indien ontwerpers
die part grootte- en akkuraatheidsbeperkings in ag neem. Die mees betekenisvolle
area van toepassing blyk kleiner en meer komplekse komponente te
wees. Die vryheid in geometrie wat moontlik gemaak word deur die Snel-
Prototipering tegnologie laat die vervaardiging toe van parte wat uitdagend is om
te vervaardig met konvensionele tegnologie soos CNC masjinering. ’n Gevallestudie
is voltooi vir ’n eenvoudige part vervaardig met die enkelkant gietstuk
vakuum-infusie weergawe van die Hars-Inspuit Giet metode asook vir ’n komplekse
part wat vervaardig is met die geslote gietstuk Vakuum Hars-Inspuit Giet
weergawe van die basiese metode. Dit het tydens die twee gevallestudies duidelik
geword dat deeglike hars infusie van kritieke belang is vir die vervaardiging van
goeie kwaliteit parte sonder enige droë kolle of lugruimtes. Dit is moontlik om die
hars infusie te verbeter deur hars inlate en uitlate asook hars kanale in die korrekte
posisies te plaas. Die korrekte posisies vir hierdie komponente is verkry deur
middel van ’n reeks simulasies met die RTM-Worx sagteware. Resultate dui ook
daarop dat Snel-Prototipering tegnologie handig te pas kom by die vervaardiging
van verbruikbare kerne vir saamgestelde materiaal parte met groter diktes. Hars
kanale kan maklik op die kerne se oppervlak geskep word om die hars verspreiding
en gevolglik part kwaliteit te verbeter. ’n Vroeë kostevoorspellings model,
gebaseer op werk voltooi deur Veldsman (1995), is saamgestel vir die gekombineerde
Snel-Prototipering en Hars-Inspuit Giet proses. Hierdie model kan gebruik
word om duur ontwerpsbesonderhede op parte te elimineer en om ’n vinnige
koste vergelyking met ander vervaardigingsprosesse te toon. Nadele van die toepassing
van Snel-Prototipering tegnieke op Hars-Inspuit Giet sluit die beperkte
gietstuk-leeftyd en beperkte akkuraatheid in.
|
35 |
Desenvolvimento e fabricação de uma mini-impressora 3D para cerâmicas / Development and manufacturing of mini 3D printer machine for ceramicsGarcia, Luis Hilário Tobler 14 January 2011 (has links)
O trabalho trata do estudo do processo de impressão tridimensional e desenvolvimento de uma impressora para a produção de corpos-de-prova cerâmicos. A técnica de impressão tridimensional pertence ao grupo de prototipagem rápida e consiste na obtenção de um corpo sólido a partir de um modelo digital de três dimensões, através do fatiamento do modelo tridimensional e da impressão seqüencial de suas respectivas fatias. Durante o processo de impressão, deposita-se um ligante sobre camadas sucessivas de pó e em cada camada, o ligante consolida o pó no formato bidimensional da fatia, que por fim soma-se as outras fatias subseqüentes, consolidando assim o formato tridimensional do modelo. Os equipamentos convencionais de impressão 3D utilizam pós a base de gesso e acrílico, onde o ligante, a base de água, fornece a primeira adesão química; posteriormente é infiltrada uma resina para fornecer uma ligação com o pó de acrílico. Na impressão de cerâmica a base de alumina ou zircônia, o desenvolvimento de ligantes tem de ser realizado visando à adesão química e orgânica combinadas antes da sinterização. Neste projeto, uma mini impressora 3D para corpos de prova foi desenvolvida e com ela foram produzidos corpos de geometria simples e seção constante, cujo projeto, custo, manutenção simplificada e econômica possibilita também o emprego de materiais agressivos nos ligantes, com risco de danificação de componentes, a exemplo de ácido fosfórico, porém com baixo custo de recuperação. Foram analisados diversos tipos pelo dimensionamento de seus aglomerados, fluidez e densidade. Obteve-se pó a base de gesso por R$15,00 o kilograma. Corpos de prova foram analisados com relação à resistência mecânica por flexão de três pontos, densidade, porosidade aparente e imagens por microscopia ótica e microscopia eletrônica de varredura (MEV). Um protótipo de uma mini-impressora foi idealizado, projetado e fabricado, soluções originais e econômicas foram propostas e na sua validação alguns conceitos necessitam de melhorias, ainda assim foram obtidos resultados promissores. Foi desenvolvida uma formulação de pó baseado em gesso que teve o custo de aproximadamente 5% do produto importado. / The work studies the three-dimensional printing process and the development of a 3D printer to produce ceramic specimen. The 3D printing technique belongs to the rapid prototype group and consists in obtaining a solid body from a three-dimensions digital model, through the slicing of the three-dimensional model and the sequential printing of their respective slices. During the printing process, a binder is deposited upon successive powder layers, and in each layer, the binder consolidates the powder into the bi-dimensional shape of the slice, which ultimately adds to the other slices that followed, consolidating the three-dimensional shape model. The conventional 3D printing equipments uses powder based in gypsum and acrylic, where the water-based binder, provides the first chemical bind; subsequently is infiltrated a resin to provide a binding with the acrylic powder. In the ceramic printing based on alumina or zirconia, the development of binders must be accomplished looking for a organic and chemical bind before sintering. In this project, a mini 3D printer for ceramic specimens was developed and built, with it were be produced bodies of simple geometry and constant section, which design, cost and simplified maintenance and cost also enable the use of aggressive materials in binders, with the risk of components damage, such as phosphoric acid, but with low cost to recovery. Were analyzed several types of powders by the sizing of its clusters, fluidity and density. Were obtained gypsum powder for $ 7.00 a kilogram. The specimen were analyzed in relation to the mechanical strength by three-point bending, density, apparent porosity and images by optical microscopy and scanning electron microscopy (SEM). A prototype of a mini 3D printer was designed, engineered and manufactured, unique and economical solutions have been proposed and in its validation some concepts need of improvement, yet promising results were obtained. It was developed a powder formulation based on gypsum that has cost about 5% of the imported product.
|
36 |
Additive Manufacturing Methodology and System for Fabrication of Porous Structures with Functionally Graded PropertiesVlasea, Mihaela January 2014 (has links)
The focus of this dissertation is on the development of an additive manufacturing system and methodology for fabricating structures with functionally graded porous internal properties and complex three-dimensional external characteristics. For this purpose, a multi-scale three-dimensional printing system was developed, with capabilities and fabrication methodologies refined in the context of, but not limited to, manufacturing of porous bone substitutes. Porous bone implants are functionally graded structures, where internally, the design requires a gradient in porosity and mechanical properties matching the functional transition between cortical and cancellous bone regions. Geometrically, the three-dimensional shape of the design must adhere to the anatomical shape of the bone tissue being replaced.
In this work, control over functionally graded porous properties was achieved by integrating specialized modules in a custom-made additive manufacturing system and studying their effect on fabricated constructs. Heterogeneous porous properties were controlled by: (i) using a micro-syringe deposition module capable of embedding sacrificial elements with a controlled feature size within the structure, (ii) controlling the amount of binder dispersed onto the powder substrate using a piezoelectric printhead, (iii) controlling the powder type or size in real-time, and/or (iv) selecting the print layer stacking orientation within the part. Characterization methods included differential scanning calorimetry (DSC)-thermo gravimetric analysis (TGA) to establish the thermal decomposition of sacrificial elements, X-ray diffraction (XRD) and dispersive X-ray spectroscopy (EDAX) to investigate the chemical composition and crystallinity, scanning electron microscopy (SEM) and optical microscopy to investigate the physical and structural properties, uniaxial mechanical loading to establish compressive strength characteristics, and porosity measurements to determine the bulk properties of the material. These studies showed that the developed system was successful in manufacturing embedded interconnected features in the range of 100-500 $ \mu m $, with a significant impact on structural properties resulting in bulk porosities in the range of 30-55% and compressive strength between 2-50 MPa.
In this work, control over the the three-dimensional shape of the construct was established iteratively, by using a silhouette extraction image processing technique to determine the appropriate anisotropic compensation factors necessary to offset the effects of shrinkage in complex-shaped parts during thermal annealing. Overall shape deviations in the range of +/- 5-7 % were achieved in the second iteration for a femoral condyle implant in a sheep model.
The newly developed multi-scale 3DP system and associated fabrication methodology was concluded to have great potential in manufacturing structures with functionally graded properties and complex shape characteristics.
|
37 |
Design and development of a layer-based additive manufacturing process for the realization of metal parts of designed mesostructureWilliams, Christopher Bryant 15 January 2008 (has links)
Low-density cellular materials, metallic bodies with gaseous voids, are a unique class of materials that are characterized by their high strength, low mass, good energy absorption characteristics, and good thermal and acoustic insulation properties. In an effort to take advantage of this entire suite of positive mechanical traits, designers are tailoring the cellular mesostructure for multiple design objectives. Unfortunately, existing cellular material manufacturing technologies limit the design space as they are limited to certain part mesostructure, material type, and macrostructure.
The opportunity that exists to improve the design of existing products, and the ability to reap the benefits of cellular materials in new applications is the driving force behind this research. As such, the primary research goal of this work is to design, embody, and analyze a manufacturing process that provides a designer the ability to specify the material type, material composition, void morphology, and mesostructure topology for any conceivable part geometry.
The accomplishment of this goal is achieved in three phases of research:
Design Following a systematic design process and a rigorous selection exercise, a layer-based additive manufacturing process is designed that is capable of meeting the unique requirements of fabricating cellular material geometry. Specifically, metal parts of designed mesostructure are fabricated via three-dimensional printing of metal oxide ceramic powder followed by post-processing in a reducing atmosphere.
Embodiment The primary research hypothesis is verified through the use of the designed manufacturing process chain to successfully realize metal parts of designed mesostructure.
Modeling & Evaluation The designed manufacturing process is modeled in this final research phase so as to increase understanding of experimental results and to establish a foundation for future analytical modeling research. In addition to an analysis of the physics of primitive creation and an investigation of failure modes during the layered fabrication of thin trusses, build time and cost models are presented in order to verify claims of the process s economic benefits.
The main contribution of this research is the embodiment of a novel manner for realizing metal parts of designed mesostructure.
|
38 |
Desenvolvimento e fabricação de uma mini-impressora 3D para cerâmicas / Development and manufacturing of mini 3D printer machine for ceramicsLuis Hilário Tobler Garcia 14 January 2011 (has links)
O trabalho trata do estudo do processo de impressão tridimensional e desenvolvimento de uma impressora para a produção de corpos-de-prova cerâmicos. A técnica de impressão tridimensional pertence ao grupo de prototipagem rápida e consiste na obtenção de um corpo sólido a partir de um modelo digital de três dimensões, através do fatiamento do modelo tridimensional e da impressão seqüencial de suas respectivas fatias. Durante o processo de impressão, deposita-se um ligante sobre camadas sucessivas de pó e em cada camada, o ligante consolida o pó no formato bidimensional da fatia, que por fim soma-se as outras fatias subseqüentes, consolidando assim o formato tridimensional do modelo. Os equipamentos convencionais de impressão 3D utilizam pós a base de gesso e acrílico, onde o ligante, a base de água, fornece a primeira adesão química; posteriormente é infiltrada uma resina para fornecer uma ligação com o pó de acrílico. Na impressão de cerâmica a base de alumina ou zircônia, o desenvolvimento de ligantes tem de ser realizado visando à adesão química e orgânica combinadas antes da sinterização. Neste projeto, uma mini impressora 3D para corpos de prova foi desenvolvida e com ela foram produzidos corpos de geometria simples e seção constante, cujo projeto, custo, manutenção simplificada e econômica possibilita também o emprego de materiais agressivos nos ligantes, com risco de danificação de componentes, a exemplo de ácido fosfórico, porém com baixo custo de recuperação. Foram analisados diversos tipos pelo dimensionamento de seus aglomerados, fluidez e densidade. Obteve-se pó a base de gesso por R$15,00 o kilograma. Corpos de prova foram analisados com relação à resistência mecânica por flexão de três pontos, densidade, porosidade aparente e imagens por microscopia ótica e microscopia eletrônica de varredura (MEV). Um protótipo de uma mini-impressora foi idealizado, projetado e fabricado, soluções originais e econômicas foram propostas e na sua validação alguns conceitos necessitam de melhorias, ainda assim foram obtidos resultados promissores. Foi desenvolvida uma formulação de pó baseado em gesso que teve o custo de aproximadamente 5% do produto importado. / The work studies the three-dimensional printing process and the development of a 3D printer to produce ceramic specimen. The 3D printing technique belongs to the rapid prototype group and consists in obtaining a solid body from a three-dimensions digital model, through the slicing of the three-dimensional model and the sequential printing of their respective slices. During the printing process, a binder is deposited upon successive powder layers, and in each layer, the binder consolidates the powder into the bi-dimensional shape of the slice, which ultimately adds to the other slices that followed, consolidating the three-dimensional shape model. The conventional 3D printing equipments uses powder based in gypsum and acrylic, where the water-based binder, provides the first chemical bind; subsequently is infiltrated a resin to provide a binding with the acrylic powder. In the ceramic printing based on alumina or zirconia, the development of binders must be accomplished looking for a organic and chemical bind before sintering. In this project, a mini 3D printer for ceramic specimens was developed and built, with it were be produced bodies of simple geometry and constant section, which design, cost and simplified maintenance and cost also enable the use of aggressive materials in binders, with the risk of components damage, such as phosphoric acid, but with low cost to recovery. Were analyzed several types of powders by the sizing of its clusters, fluidity and density. Were obtained gypsum powder for $ 7.00 a kilogram. The specimen were analyzed in relation to the mechanical strength by three-point bending, density, apparent porosity and images by optical microscopy and scanning electron microscopy (SEM). A prototype of a mini 3D printer was designed, engineered and manufactured, unique and economical solutions have been proposed and in its validation some concepts need of improvement, yet promising results were obtained. It was developed a powder formulation based on gypsum that has cost about 5% of the imported product.
|
39 |
Análise comparativa da acurácia de modelos impressos, obtidos a partir de escaneamento intra-oral / Comparative analysis of the accuracy of printed casts, obtained from intraoral scanningIgai, Fernando 28 November 2018 (has links)
A confecção de trabalhos protéticos em um fluxo digital é possível a partir do escaneamento intra-oral e confecção da Prótese via CAD/CAM. A tecnologia atual de impressão 3D permite a obtenção de um modelo impresso, para a realização de determinados procedimentos. Entretanto, é necessário analisar e comparar estes modelos com os modelos de gesso, uma vez que existe uma diferença significativa na forma de obtenção, assim como, nos custos de cada tipo de modelo. O presente estudo teve como objetivo realizar uma análise da acurácia entre modelos impressos, obtidos por meio de escaneamento intra-oral e impressão 3D, e modelos de gesso obtidos pelo método de moldagem convencional. Foi utilizado um manequim odontológico como modelo mestre e foram confeccionados dez modelos de gesso (n= 10), pela técnica de moldagem da dupla impressão com silicone de adição. Foram utilizados dois tipos de escâneres intra-orais e dois tipos de impressoras 3D, que formaram quatro grupos experimentais com dez modelos por grupo (n= 10). Os modelos físicos de gesso e impressos foram comparados com o modelo mestre por meio de análises de medições lineares em seis sítios de medições, com o uso de uma máquina de medição por imagem (Quick Scope, Mitutoyo®). A análise dos modelos impressos incluiu as possíveis interações entre os fatores principais tipo de impressora, tipo de escâner e sítios de medições. Os resultados mostraram que em relação ao modelo mestre, no geral, as discrepâncias dos modelos de gesso foram menores que as discrepâncias dos modelos impressos. A análise das interações dos fatores principais indicou que o tipo de impressora exerceu a maior influência na acurácia dos modelos impressos, seguido do fator sítio de medição e tipo de escâner. Pôde-se concluir que os modelos de gesso apresentaram uma acurácia superior quando comparados com os modelos impressos. O acabamento superficial dos modelos impressos exerceu influência na sua acurácia. / The preparation of prosthetic restoration in a digital flow is possible using intraoral scanning and confection of the prosthesis via CAD/CAM. The current 3D printing technology allows the making of a printed cast, for performing certain laboratory procedures. However, it is necessary to analyze and compare these casts with the gypsum casts, since there is a significant difference in the form of obtaining, as well as, in the costs of each type of cast. The objective of the present study was to perform a comparative study of the accuracy of printed casts, obtained through intraoral scanning and 3D printing, and gypsum casts, obtained through the conventional impression. A dental mannequin was used as the master model and ten gypsum casts (n=10) were obtained, using double impression technique with polyvinyl siloxane. Two types of intraoral scanners and two types of 3D printers were used, which formed four experimental groups with ten models per group (n=10). The real gypsum and printed casts were compared to the master model by linear measurements in six sites, using an image-measuring machine (Quick Scope, Mitutoyo®). The analysis of the printed models included possible interactions between the factors type of printer, type of scanner and measurement sites. The results showed that, in relation to the master model, in general, the discrepancies of the gypsum casts were smaller than the discrepancies of the printed casts. The interactions of the factors analysis indicated that the type of printer exerted the greatest influence on the accuracy of the printed casts, followed by the site measurement and type of scanner. It was conclude that the gypsum casts presented superior accuracy when compared to the printed casts. The surface finish of the printed casts exerted influence in its accuracy.
|
40 |
Projeto conceitual de órtese estabilizadora para o ombro / Concept and development of shoulder stabilizer orthoseAssad, Danielle Aline Barata 26 March 2018 (has links)
A subluxação do ombro é a complicação musculoesquelética mais comum das afecções do Sistema Nervoso Central e Periférico, que leva a diminuição do movimento, da função e aumento de dor. Um dos recursos auxiliares utilizados é a órtese que visa corrigir a deformidade, diminuir a dor e proporcionar a função. Este trabalho objetiva projetar e desenvolver o conceito de uma órtese personalizada estabilizadora de ombro. A metodologia de desenvolvimento de projeto de produto esta dividida em três fases: informacional, conceitual e projeto preliminar. Na fase informacional foi realizada pesquisa bibliográfica, de patentes e de mercado e foram entrevistados 30 prováveis usuários; coletados os dados antropométricos, força muscular manual e goniometria. Na fase conceitual, baseado na fase informacional e a partir da Metodologia TRIZ (Teoria da Resolução de Problemas Inventivos) foi proposto um desenho original de órtese híbrida, personalizada e manufaturada em tridimensional, usando estruturas rígidas e faixas de tração, que estabilizem o ombro, diminua a dor e permita a função. A fase do projeto preliminar foi composta por escaneamento tridimensional e uso de softwares que transformam uma imagem digitalizada em formato STL®. Foram realizadas sucessivas evoluções do projeto com geração de desenhos e peças prototipadas que foi avaliada por um usuário. Na fase informacional, a pesquisa de patentes e de mercado mostrou que há uma predominância dos modelos de órtese estabilizadora de ombro com material flexível onde o principal meio de tração é dado por faixas na diagonal e transversal ao tronco, tendendo a posicionar o ombro em rotação interna. Enquanto os usuários relataram expectativa de uma órtese que corrija o posicionamento, tenha melhor conforto térmico e tátil, menos cheiro e de fácil limpeza. O conceito desenvolvido foi: órtese personalizada, fácil de higienizar e de por/tirar, resistente, articulada, leve, em plástico ABS (acrilonitrila, butadieno e estireno) impressão tridimensional, com veste nos dois braços, com faixas de tração rígidas fixadas à cintura, visando à correção da subluxação do ombro com conforto, menor dor além de permitir função. O teste com usuário corroborou com o conceito, pois o protótipo preliminar apresentou bom acoplamento ao tronco, tração satisfatória e possibilidade de realizar um maior número de atividades diárias com menos dor e sensação de cansaço. / The shoulder subluxation is the most common musculoskeletal complication of Central and Peripheral Nervous System disorders, which leads to a decrease in movement, function and increase in pain. One of the resources used to help with this issue is the orthosis that aims to correct the deformity, decrease the pain and provide function. This work aims to design and develop the concept of a personalized shoulder stabilizing orthosis. The methodology used on the product design is divided into three phases: informational, conceptual and preliminary design. In the informational phase, bibliographic, patent and market research were carried out and 30 potential users were interviewed; anthropometric data, manual muscle strength and goniometry were collected. In the conceptual phase, based on the informational data and using TRIZ Methodology (Theory of Inventive Problem Solving), an original concept design of a hybrid orthosis, personalized and manufactured three-dimensional, using rigid structures and traction bands, was proposed to stabilize the shoulder, reduce pain and allow function. The preliminary design phase consisted of tridimensional scanning and the use of software that transformed a scanned image into STL®. Successive evaluations of the project were carried out with generation of designs and prototyped parts - which the user has evaluated. During the informational phase, the patent and market research demonstrated a predominance of the stabilizing orthosis models using flexible material where the main form of traction was given by diagonal and transverse bands to the trunk, tending to position the shoulder in internal rotation. Users have reported the expectation that this orthosis could correct the shoulder positioning and that it has a better thermal and tactile comfort, less smell and easier to clean. The concept developed was: a personalized orthosis, easy to sanitize and to put on/take off, resistant, articulated, lightweight, in ABS (Acrylonitrile butadiene styrene), three-dimensional printing, with a vest in both arms, rigid traction bands fixed to the waist, aiming to correct the shoulder subluxation with comfort, less pain while allowing function. The user test corroborated with the concept, as the preliminary prototype presented good trunk coupling, satisfactory traction and the possibility to perform a greater number of daily activities with less pain and less fatigue caused by limb weight.
|
Page generated in 0.1094 seconds