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The use of CT scan and stereo lithography apparatus technologies in a canine individualized rib prosthesis

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The use of CT scan and stereo lithography apparatus technologies in a canine individualized rib prosthesis

To design and fabricate canine rib prosthesis with full geometric shape using computed tomography (CT) scan combined with computer-aided design (CAD) and stereo lithographic (SLA) technologies and to evaluate the accuracy of this method.

After scanned on 64 rows helical CT, the cortex part of the right 7th rib was selected as the prototype for design and manufacture of the rib prosthesis and image data were stored as DICOM format. Three-dimensional (3D) surface reconstruction was applied to produce 3D image of the 7th rib and results were outputted as STL format which were then modified by UG software for establishment of CAD model.

The rib prosthesis with full geometric shape was obtained based on CT scanning and SLA technique. About 30,000 point cloud data were acquired after 3D laser scan of the ribs. When comparing the rib prosthesis with the rib prototype, the maximum positive deviation, maximum negative deviation, average deviation and standard deviation were 1.764 mm, −2.126 mm, 0.183/−0.253 mm and 0.346 mm, respectively. There were about 88.17% of the point cloud data within the range of 0.5 mm.

It is feasible to design and fabricate rib prosthesis with full geometric shape by using CT scanning technology combined with CAD and SLA technologies. This method is fast, convenient and precise for manufacturing prosthesis. Optimization and improvement could be processed based on the deviation suggested by the scanning.

Copyright © 2013 Published by Elsevier Ltd.

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Diamond-structured hollow-tube lattice Ni materials via 3D printing

Light-weight and high-strength materials have attracted considerable attention owing to their outstanding properties, such as weight-reducing, acoustic absorption, thermal insulation, shock and vibration damping. Diamond possesses specific stiffness and strength arising from its special crystal structure. In this work, inspired by the diamond crystal structure, hollow-tube nickel materials with the diamond structure were fabricated using a diamond structured polymer template based on the Stereo Lithography Appearance technology. The diamond structured template was coated with Ni-P by electroless plating. Finally, the template was removed by high temperature calcinations. The density of the hollow tube nickel materials is about 20 mg/cm3. The morphology and composition of the resultant materials were characterized by scanning electron microscope, energy-dispersive spectrometry, and X-ray diffraction. The results showed that the surface of the Ni film was uniform with the thickness of 4 m. The mechanical property was also measured by stress and strain tester. The maximum compression stress can be reached to 40.6 KPa.

Unable to display preview.Download preview PDF.

Unable to display preview.Download preview PDF.

Evans AG, Hutchinson JW, Fleck NA, Ashby MF, Wadley HNG.

Barrett DJ. Vibration-damping structural member US Patent: 5087491, 1992

Jeker R, Reiser R. Vibration-damping mount US Patent: 5238215, 1993

Maloney KJ, Roper CS, Jacobsen AJ, Carter WB, Valdevit L, Schaedler TA.

Maloney KJ, Fink KD, Schaedler TA, Kolodziejska JA, Jacobsen AJ, Roper CS.

Brandner JJ, Anurjew E, Bohn L, Hansjosten E, Henning T, Schygulla U, Wenka A, Schubert K.

Moreau LM, Ha DH, Bealing CR, Zhang H, Hennig RG, Robinson RD.

Zheng X, Lee H, Weisgraber TH, Shusteff M, De Otte J, Duoss EB, Kuntz JD, Biener MM, Ge Q, Jackson JA, Kucheyev SO, Fang NX, Spadaccini CM.

Verdooren A, Chan HM, Grenestedt JL, Harmer MP, Caram HS.

Tappan BC, Huynh MH, Hiskey MA, Chavez DE, Luther EP, Mang JT, Son SF.

Zou J, Liu J, Karakoti AS, Kumar A, Joung D, Li Q, Khondaker SI, Seal S, Zhai L.

Hu H, Zhao Z, Wan W, Gogotsi Y, Qiu J.

Schaedler TA, Jacobsen AJ, Torrents A, Sorensen AE, Lian J, Greer JR, Valdevit L, Carter WB.

Mecklenburg M, Schuchardt A, Mishra YK, Kaps S, Adelung R, Lotnyk A, Kienle L, Schulte K.

Xiong J, Mines R, Ghosh R, Vaziri A, Ma L, Ohrndorf A, Christ HJ, Wu L.

Zhu C, Han TYJ, Duoss EB, Golobic AM, Kuntz JD, Spadaccini CM, Worsley MA.

do Rosrio JJ, Lilleodden ET, Waleczek M, Kubrin R, Petrov AY, Dyachenko PN, Sabisch JEC, Nielsch K, Huber N, Eich M, Schneider GA.

Schaedler TA, Jacobsen AJ, Carter WB.

Zheng X, Deotte J, Alonso MP, Farquar GR, Weisgraber TH, Gemberling S, Lee H, Fang N, Spadaccini CM.

Kitson PJ, Rosnes MH, Sans V, Dragone V, Cronin L.

Sun K, Wei TS, Ahn BY, Seo JY, Dillon SJ, Lewis JA.

Joe Lopes A, MacDonald E, Wicker RB.

Woesz A, Rumpler M, Stampfl J, Varga F, Fratzl-Zelman N, Roschger P, Klaushofer K, Fratzl P.

Jacobsen AJ, Barvosa-Carter W, Nutt S.

Philos Trans R Soc A-Math Phys Eng Sci,

© Science China Press and Springer-Verlag Berlin Heidelberg 2016

Key Laboratory of Bio-inspired Smart Interfacial Science and Technology of Ministry of Education; Beijing Key Laboratory of Bio-inspired Energy Materials and Devices, School of Chemistry and Environment

Xu, J., Gao, Y., Huang, H. et al. Sci. China Chem. (2016) 59: 1632.

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Elastic buckling of externally pressurized Cassini oval shells with various shape indices

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Elastic buckling of externally pressurized Cassini oval shells with various shape indices

The elastic buckling of externally pressurized Cassini oval shells is examined.

The effect of shape index varying from 0 to 0.99 on the buckling is explored.

Thekc=0.1Cassini oval geometry appears to be a favorable configuration.

This study examines the effect of shape index on the elastic buckling of Cassini oval shells under uniform external pressure. Shells are evaluated under a uniform wall thickness (2mm) and capacity (3.63106mm3), with the shape index,kc=c/a, ranging from 0 to 0.99. Several numerical computations, involving linear elastic bifurcation analysis and geometrically nonlinear elastic analysis including eigenmode imperfections, are conducted for these shells. Some of them are investigated experimentally. The results show that a Cassini oval shell with a stable character seems to be an unfavorable shape due to its low load-carrying capacity, which is at variance with previous findings regarding this problem. Notably, thekc=0.1Cassini oval geometry, exhibiting a high load-carrying capacity, appears to be a favorable shape in various fields such as underwater tanks, pressure hulls, and artificial capsules.

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ATSmakeݹ˾ʼӪƷƣATSmakeƷƳһSLAͼ3DӡATSmake 3DӡATSmakeArtisan MakeļΪ죬ATSmakeƷƵרҵ2011ݹ˾һҴҵ΢ҵϴ¡ѣ8ӢNorgeͬSLS

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Stereolithography (SLA) in

Welcome to the premier industrial source for Stereolithography (SLA) in New York – Upstate. These companies offer a comprehensive range of Stereolithography (SLA), as well as a variety of related products and services. provides numerous search tools, including location, certification and keyword filters, to help you refine your results. Click on company profile for additional company and contact information.HomeSupplier DiscoveryStereolithography (SLA) Suppliers serving Upstate New York

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A company that makes stock products, which may be sold directly to customers and/or through distributors.

A company that makes custom components or finished products according to a customers specifications.

A company that performs a custom process to a component or product manufactured elsewhere. Examples include polishing, anodizing and plating.

A company that provides a service such as rental, repair, security, training, cleaning, etc.

A sales company that is contracted by a manufacturer to sell their products.

Remanufacturers rebuild products to OEM specifications by using a combination of used, repaired and new parts.

A company that sells products manufactured by a 3rd party.

A company that offers design, selection, sourcing and installation of equipment/machinery (manufactured by themselves or a 3rd party) for a custom solution conveyor, robotic, factory automation or other system.

An organization, also known as an industry trade group, founded by businesses that operate in a specific industry that collaborates between its member companies.

Quality Certifications are issued to suppliers by an accredited third party, verifying that the supplier complies with established quality standards.

Quality standards are usually documents written by developing bodies such as the International Organization for Standardization (ISO) or trade organizations such as the Society of Automotive Engineers (SAE). Quality standards are used to compare an organization to what the authorities say are best practices for a quality management system. Quality standards can either be written in terms general enough to be used across any industry or written with requirements for a specific industry. Industry specific quality standards may be written with the help of experts in that industry.

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Other Certifications/Registrations are general compliances, memberships, agreements or qualifications that do not relate to a quality management system or to a companys ownership status. These may include certifications that are issued to individuals or an entire company. Other Certifcations/Registrations may or may not require third party verification; in some cases, an organization may self-certify by issuing a certificate of compliance to a given standard or regulation. Safety and security programs often fall into this group. Examples of other certifications/registrations include ITAR Registered and GSA Approved.

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Stereolithography (SLA) Suppliers serving Upstate New York

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Custom manufacturer of medical devices and surgical smoke evacuation systems. Products such as inline and replacement filters, tubing, adapters, wands and accessories are available. Capabilities include stereo lithography, rapid prototyping, metal fabrication, assembly and contract manufacturing services.

Manufacturing Of Rapid Prototyping Materials That Replicate Performance Parameters Of Production Materials From Thermoplastic Elastomers To Polyethylene & Polypropylene. Solutions For Stereolithography & Selective Laser Sintering Technologies. Solid Imaging Materials. General Purpose Materials To Flexible Rubber-Like Characteristics. Used Directly In Prototype Parts Or Small Quantity Production Parts; Also Used To Develop Precise Tooling For Other Rapid Prototyping Technologies

Custom manufacturer of blow-molded plastic bottles and specialty parts. Products include closures, tooling and molds. Capabilities include injection and blow molding and rapid prototyping services. Markets served include electronics, plastic packaging, medical and instrumentation sectors.

Custom manufacturer of plastic injection molded parts. Capabilities include CNC machining, milling and turning, wire and sinker EDM, rapid prototyping, tooling, over and insert molding, bonding, soldering, welding, hot stamping, tapping, reaming, drilling and heat staking services. Markets served include medical, automotive, telecommunication, electronics, military, and aerospace industries.

Product concept development, industrial, mechanical & electronic design, engineering analysis, manufacturing engineering & rapid prototyping services.

Arnprior Rapid Manufactuirng Solutions

Virtual & appearance modeling, stereolithography (SLA), selective laser sintering (SLS), rubber molding, casting & thermoforming, precision sheet metal fabrication, CAD/CAM CNC machining.

Manufacturer Of Cnc Machined Parts, Castings & Plastic Prototypes. Services Include Sil Screening, Debranding & Prototype Packaging.

Injection Molding from 3D Printed Molds

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mall part

Method of manufacturing: CNC machining

Surface treatment:natural smooth surface

Size:According to specified designing

Stereo lithography Appearance (SLA) Rapid Prototyping

Stereo lithography is the heart of ProtoCAMs rapid prototyping service, turning your 3D CAD drawing into a solid object.

Stereo lithography prototypes can be used as master patterns for injection molding core and cavity inserts, thermoforming,

blow molding, and various metal casting processes.

Key benefits of Stereo lithography Rapid Prototyping

1.Time saving: it can fabricate your SLA prototype in less than3 days

4.Epoxy resin is resilient enough to be used for testing

5.Stereo lithography is well suited to small lot manufacturing of prototype or end-use parts

6.Stereo lithography investment casting patterns allow rapid production of metal prototypes

It is the original Rapid Prototyping technique, and still the most commonly used.

It utilizes a light-sensitive liquid polymer.

It requires post-curing since laser is not intense enough to fully cure.

Parts are somewhat brittle and have a tacky surface.

There is no milling process, so dimensional accuracy can suffer.

Support structures are typically required.

The process is simple: Neither milling nor masking steps are required.

Uncured material should be expected to emit toxic fumes. Thorough ventilation is necessary.

When a low number of prototypes is needed (1-10).

Plastic piece rapid-tooling patterns.

Focus group and presentation models.

Small parts with complicated structures prototyping ,like toys

Address: Building A5,Quan bao Industry Park, Guang ming Road,

Shi yan, Bao an district, Shenzhen, Guang dong, China

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ܺӼҳTS308:һͥĴӡ

ܺӼҳTS308:һͥĴӡ

ձѧ֧3Dӡ ɹֲ

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SLA̻ӡ3DӡԻSLAְģ-3Dӡ

Materialise Magics22ʹÿĽṹ3Dӡ

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