Abstract: The present invention is a dental implant utilizing a polymeric dental post. The actual prosthetic portion of the implant may also be manufactured from a polymer. Various post designs are disclosed for setting and securing the post in a patient's jaw. Numerous polymers are disclosed and may be blended to achieve desired characteristics for both the post and prosthetic.

Abstract: The present invention provides a method for making an ophthalmic device. In particular, the present invention provides a method for production of a contact lens by means of stereolithography. A preferred stereolithography technique is based on polymerization and solidification of a contact lens forming liquid material by actinic irradiation one layer at a time. In addition, the present invention provides systems and methods for making a contact lens for a specific patient based on the prescription.

Abstract: A method of forming a functional razor cartridge for repeated shaving comprises rapid prototyping a housing of a razor cartridge. The housing has a front wall, a rear wall and opposing side walls disposed transverse to and between said front and rear walls. The method further comprises loading a metal insert with one or more elongate blade assemblies and disposing the metal insert in the housing such that the one or more blade assemblies extend between the opposing side walls of the housing.

Abstract: An artificial bone forming method, comprising a) a powder layer forming step (32) for forming, into a flat powder layer (6), a powder bone material (5) having biocompatibility and hardening by hydration, b) a partial hardening step (34) for jetting an aqueous solution (7) with biocompatibility to a part of the powder layer to harden a jetted portion (6a) by hydration, and c) an artificial bone forming step (36) for repeating the steps a) and b) for lamination to form a specified artificial bone (9) of a predetermined three-dimensional structure in which the hardened portions (6a) are connected to each other.

Abstract: An integrated additive manufacturing cell (IAMC) that combines conventional manufacturing technologies with additive manufacturing processes is disclosed. Individual IAMCs may be configured and optimized for specific part families of complex components, or other industrial applications. The IAMCs incorporate features that reduce hardware cost and time and allow for local alloy tailoring for material properties optimization in complex components.

Abstract: In illustrative implementations of this invention, a mechanical clock is produced in a manner such that, once its separate parts are made, the clock requires no further assembly. In one implementation of this invention, a mechanical clock is designed using standard CAD (computer-aided design) modeling tools and made with a rapid prototyping machine. The support material used in rapid prototyping is then removed. Once the support material is removed, the clock runs without any additional assembly. In this implementation, the clock contains all the components that are required and they are all constructed in the rapid prototyping process.

Abstract: The invention provides a method and system for substantially coterminous modification of a patient situation and a manufactured prosthetic to achieve the desired fit. Rather than utilizing a serial approach, a parallel approach is taken where both patient situation and prosthetic device can be modified at the same time (or substantially the same time).

Abstract: There are provided systems, methods and apparatuses related to bone augmentation shells. In particular, in accordance with an aspect, there is disclosed an apparatus for bone augmentation. The apparatus includes a biocompatible body being shaped to fit over basal supporting bone structure. The body has an interior surface defining a cavity into which bone growth material may be inserted. Additionally, the body includes a rib portion located at an apex of the body, a first surface extending downward on a first side from the rib portion and a second surface extending downward on a second side from the rib portion. At least a portion of the first and second surfaces is roughened to have a micro-topography conducive to soft tissue attachment.

Abstract: There is provided an optical modeling apparatus that forms a model of a desired shape by sequentially forming hardened layers by irradiating a light-curable resin with light. The apparatus includes a first light source that emits a light beam for plotting on the resin, a scanning device that scans the light beam from the first light source over the resin, a second light source that emits light that irradiates one fixed region of the resin at a time, and a spatial light modulator that spatially modulates the light from the second light source to blanket-expose a specified region of the resin. The light beam from the scanning device and the light from the spatial light modulator form each hardened layer.

Abstract: A printing system for creating a three-dimensional object. The printing system includes a plurality of printheads including a first printhead configured to print a first material and a second printhead configured to print a second material. The system includes one or more curing mechanisms for curing the printed materials. The system includes at least one object incorporation device configured to incorporate a non-printed object into the three-dimensional object when partially complete. At least one printhead is configured to print one or more electrical connections to the incorporated object.

Abstract: The invention relates to a method for producing a three-dimensional object by solidification of a material solidifiable under the action of electromagnetic radiation by means of energy input via an imaging unit comprising a predetermined number of discrete imaging elements (pixels), The method comprises performing solidification with exposure using bitmap mask. The bitmap mask may be formed from a stack of bitmap data provided by an overlap analysis of a three-dimensional volume completely or partially enclosing a three-dimensional model of at least a part of the three-dimensional object to be produced. Alternatively, bitmap mask may be formed from a two-dimensional data set comprising overlap information. Solidification may be performing with exposure using bitmap mask generated “on the fly”. The invention is also directed to devices, and a computer and a data carrier useful for performing or executing the method.

Abstract: Fuselage sections of an aircraft are joined using splice elements that compensate for gaps caused by mismatches between mating surfaces on the fuselage sections. The fuselage sections are virtually assembled using computer models that are based on non-contact measurements of as-built fuselage sections. The virtually assembled fuselage sections are used to map the gaps between the mating surfaces. The mapped gaps are used to produce tool inserts having profiles that reflect the dimensions of the gaps. The tool inserts are used to manufacture splice elements having profiles that fill the gaps when the fuselage sections are assembled and joined, thereby eliminating the need for shims and spaces to fill the gaps.

Abstract: A custom device and method for fabricating the custom device includes marking a body with reference points and/or other indicators. Multiple images of the body from multiple angles are then obtained. The images are used to determine the contours of the body and the other markings are located and used to design the custom device. The custom device can be fabricated as a single piece structure or in multiple pieces that are assembled to complete the custom device.

Abstract: Methods, apparatuses, computer program products, devices and systems are described that include accepting one or more blood vessel sleeve dimensions based on blood vessel data from an individual; and making a rapid-prototyped blood vessel sleeve at least partly based on the one or more blood vessel sleeve dimensions.

Abstract: A method and apparatus are described for forming a structure on a substrate. The structure may be a circuit element. The method uses a digital specification 910 for forming the structure, including specifications for printing and curing. The structure is printed (step 112) using a drop-on-demand printer 400, wherein the printing dispenses at least one material on the substrate 420 according to the digital specification 910. The structure is cured (step 130) by irradiating the dispensed material from one or more electromagnetic radiation sources 520, 525 in the printer 400, wherein curing parameters are specified by the digital specification 910 to obtain a desired electrical property when the structure is a circuit element. The curing specification may specify the intensity of the irradiation and the location of irradiation points in the print region.

Abstract: A closed-loop control method for an electron beam freeform fabrication (EBF3) process includes detecting a feature of interest during the process using a sensor(s), continuously evaluating the feature of interest to determine, in real time, a change occurring therein, and automatically modifying control parameters to control the EBF3 process. An apparatus provides closed-loop control method of the process, and includes an electron gun for generating an electron beam, a wire feeder for feeding a wire toward a substrate, wherein the wire is melted and progressively deposited in layers onto the substrate, a sensor(s), and a host machine. The sensor(s) measure the feature of interest during the process, and the host machine continuously evaluates the feature of interest to determine, in real time, a change occurring therein. The host machine automatically modifies control parameters to the EBF3 apparatus to control the EBF3 process in a closed-loop manner.

Abstract: A method and apparatus for making a three-dimensional object from a solidifiable material such as a photopolymer is shown and described. In accordance with the method, positions relative to a build axis are subdivided into first and second exposure data subsets, and the first and second exposure data subsets are solidified in alternating sequences to reduce the surface area of solidified material in contact with a solidification substrate.

Abstract: A custom brace and method for fabricating the custom brace includes marking a body with reference points and/or other indicators. Multiple images of the body from multiple angles are then obtained. The images are used to determine the contours of the body and the other markings are located and used to design the custom brace. Fenestrations can be added to the brace design. The custom brace can be fabricated with the fenestrations as a single piece structure or in multiple pieces that are assembled to complete the custom device.

Abstract: A method is for repairing and/or modifying component parts of a gas turbine. First, at least one, particularly damaged section of the component part that is to be repaired is cut out of the component part. In addition, if it does not exist, a data record is generated for a replacement part that is to be produced. The replacement part is subsequently produced with the aid of a rapid manufacturing process. Subsequently, the replacement part produced is integrated into the component part that is to be repaired.

Abstract: A prosthetic limb has an outer surface that is a mirror image of an intact limb. The intact limb is scanned and the surface data is manipulated to create a virtual mirror image. The end of the amputated limb is also scanned to obtain socket data. A virtual limb is designed using a computer program based upon the mirror image and end of the amputated limb data. The computer program is also used to design a removable fairing that provides color and texture to the prosthetic limb.

Abstract: A printer system is provided for developing a three dimensional (3D) printed structure. The system includes a plurality of spaced apart sets of printing devices. A conveyor system is arranged to serially convey a print medium in register with each set so that printed voxels from each successive set can form successive layers of the 3D printed structure upon the print medium. A placement mechanism is configured to place an object upon layers of the 3D printed structure.

Abstract: A three-dimensional modeling apparatus includes a stage, a supply mechanism, a head, a movement mechanism, and a lifting and lowering mechanism. On the stage, a powder material is accumulated. The supply mechanism supplies the powder material on the stage for each predetermined layer thickness. The head ejects a liquid for forming a three-dimensional object to the powder material on the stage. The liquid is capable of binding the powder material. The movement mechanism moves the stage so that the liquid is supplied from the head to the powder material by the predetermined layer thickness. The lifting and lowering mechanism lowers the stage for each predetermined layer thickness.

Abstract: A method (10) for fabricating a hearing aid using a self-contained hearing aid production laboratory employing three dimensional printing technology. The method (10) comprises the steps of conducting audiometric testing of an individual with a hearing impairment (12, 14); selecting and customizing a product design for the hearing aid to be produced (16, 18); producing the selected and customized hearing aid (20, 22, 24); and performing final adjustments to the produced hearing aid (26, 28).

Abstract: Fuselage sections of an aircraft are joined using splice elements that compensate for gaps caused by mismatches between mating surfaces on the fuselage sections. The fuselage sections are virtually assembled using computer models that are based on non-contact measurements of as-built fuselage sections. The virtually assembled fuselage sections are used to map the gaps between the mating surfaces. The mapped gaps are used to produce tool inserts having profiles that reflect the dimensions of the gaps. The tool inserts are used to manufacture splice elements having profiles that fill the gaps when the fuselage sections are assembled and joined, thereby eliminating the need for shims and spaces to fill the gaps.

Abstract: A method of producing an object by sequentially printing layers of construction material one on top of the other, the method comprising: providing the construction material at a first lower temperature; flowing the construction material through a heated flow path in a flow structure to heat the construction material and delivering the heated construction material to a heated reservoir in a printing head; and dispensing the heated construction material from the reservoir to build the object layer by layer.

Abstract: Disclosed herein are devices, systems and methods for the automated design and manufacture of patient-specific/patient-matched orthopedic implants. While the embodiments described herein specifically pertain to unicompartmental resurfacing implants for the knee, the principles described are applicable to other types of knee implants (including, without limitation, other resurfacing implants and joint replacement implants) as well as implants for other joints and other patient-specific orthopedic applications.

Abstract: A physical model of at least a portion of a patient's dentition has model dental surfaces corresponding to real dental surfaces of the patient's dentition. The physical model includes one or more targets, each configured for facilitating placement of an orthodontic appliance on the model at a desired location. The targets lack mechanical stops that are outwardly protruding from the original model dental surfaces. Also provided are a method of manufacturing a physical model for use in indirect bonding procedures, a method for indirect bonding for use in an orthodontic procedure, a method for providing an indirect bonding transfer tray for use in an orthodontic procedure, and a system for providing a physical model for use in indirect bonding orthodontic procedures.

Abstract: Dental prosthesis, systems, and methods of forming and using a dental prosthesis, are provided. An example of a dental prosthesis includes a first manufactured portion shaped to substantially conform to the three-dimensional surface of a root of a tooth to be replaced and a second manufactured portion shaped to substantially conform to the three-dimensional surface of a crown of the tooth. Furthermore, customized manufactured splints to position and fixate a tooth-shaped prosthesis, are provided. Furthermore, a CAD/CAM based methods of and a systems for manufacturing a customized dental prosthesis are provided. The tooth can be scanned to determine its three-dimensional shape and substantially copied using an imaging system in-vitro like a 3D scanner or in-vivo like a cone beam CT system and CNC machinery. Biocompatible material that is suitable to be integrated into the extraction socket and adopted by existing tissue forming the socket can be manufactured or engineered.

Abstract: A system for implanting a temporary anchorage device in a jaw bone of a patient makes use of a digital representation of at least a portion of the patient's dental arch, including teeth and corresponding roots, in order to select a temporary anchorage device (TAD) implant site that does not interfere with a tooth root. A surgical guide relates the information from the digital representation to an actual location in the patient's jaw bone. The surgical guide is formed to fit over at least a portion of the occlusal, buccal, labial, and/or lingual surfaces of the dental arch proximate to the selected TAD implant site and includes a physical and/or visual marker that indicates the selected TAD implant site.

Abstract: To select a scan distance to be used in scanning a wafer with an implant beam, a dose distribution along a first direction is calculated based on size or intensity of the implant beam and a scan distance. The scan distance is the distance measured in the first direction between a first path and a final path of the implant beam scanning the wafer along a second direction in multiple paths. A relative velocity profile along the second direction is determined based on the dose distribution. Dose uniformity on the wafer is calculated based on the wafer being scanned using the relative velocity profile and the determined dose distribution. The scan distance is adjusted and the preceding steps are repeated until the calculated dose uniformity meets one or more uniformity criteria.

Abstract: To generate course head assignments for a multihead composite material application machine having a set of heads, a set of paths for a ply for a composite part is received and it is determined whether each path of the set of paths complies with a head characteristic for the set of heads. In addition, a special head of the set of heads is assigned to a non-standard path of the set of paths in response to determining the non-standard path does not comply with the head characteristic and ones of the set of heads are assigned to corresponding ones of the set of paths in response to the ones of the set of paths being in compliance with the head characteristics. Furthermore, a constellation of head locations is calculated in response to the set of paths being in compliance with the head characteristic and the set of heads are assigned to the constellation of head locations in response to calculating the constellation of head locations.

Abstract: A volume element (voxel) printing system for printing a three-dimensional object includes a first printhead group having a plurality of first printheads configured to print a first voxel layer on a substrate; at least one second printhead group having a plurality of second printheads downstream from the first group, the second printhead group configured to print a subsequent voxel layer on at least part of the first layer, said second printheads being reconfigurable as backup printheads for the first printheads in case of failure; a conveyor configured to convey the substrate past the printhead groups; and a control system configured to control and monitor the printhead groups, the object insertion device, and the conveyor, and dynamically to reconfigure the second printheads upon detection of failure of a first printhead. The at least one second printhead group is vertically spaced from the substrate by a greater distance than the first printhead group.

Abstract: Methods are provided for solid free-form fabrication of an article without using a slice stack file. These apply ray casting a number of times to an electronic representation of the article to create data objects for use directly as printing instructions or which are convertible into printing instructions. The data objects may be utilized as they is generated or after they are created for a portion or all of the article. After utilization, the data objects may be discarded or stored for later use. Layer-specific layer thickness and other-direction resolution parameters may be input and utilized in selecting the number of rays to be cast, their origination points, and their directions, thus permitting controllable variation in detail precision in any direction. Error diffusion techniques may be used to improve fabricated part integrity. Improved intermachine portability is provided. Method, system, code, and media claims are included.

Abstract: Producing a three-dimensional multi-material component whereby successive layers of at least one material are printed by a drop ink-jet-type printer including cutting a representation of the multi-material component into remarkable objects; cutting the representation of the component into print layers, as a function of the remarkable objects; for each print layer, establishing a plurality of discrete spatial print path trajectories; for each print layer and for each discrete spatial trajectory, establishing an assembly of printing parameters which are dependent on the nature of the deposited materials and the deposition conditions thereof; and establishing a rule for the spatial and temporal sequencing of the print path of the print layers and of the discrete spatial trajectories as a function of the objects, the relative three-dimensional arrangement thereof and the characteristics of the printing device.

Abstract: A method and system for building a three-dimensional model, which include performing a subtractive removal process on at least one material feedstock to form a plurality of base seeds, performing an additive deposition process to deposit at least one material on at least a portion of a base seed target surface, and performing an assembly process to combine the plurality of base seeds to form at least a portion of the three-dimensional model.

Abstract: In a method of providing a material amount for a generative manufacturing method, a three-dimensional object (2) is formed by selectively solidifying layers of a material at locations corresponding to the cross-section of the object (2) in the respective layers. It is the object of the present invention to provide a method, by which the quality of the manufactured objects is reproducibly recorded and, thus, further improved. Therefore, the method is characterized by the steps of: providing at least one first material amount, which is characterized by at least one feature; detecting data, which relate to the at least one feature of the first material amount; and storing data, which relate to the at least one feature of the first material amount.

Abstract: The invention relates to a method for fabricating dental components. A set of geometric data is provided for the three-dimensional description of at least one desired dental component, and based on these geometric data a three-dimensional CAD model of the dental component is created. The CAD model processes the geometric data in the form of layer data to generate numerous CAD model layers which are suitable for use in a laser sintering or laser melting process. The laser sintering or laser melting process is then carried out, based on the layer data for each individual CAD model layer, and with computer assistance a powdered material is correspondingly applied in layers on a fabrication platform. Following the laser sintering or laser melting process, the body of the dental component having the resulting layered construction is transferred to a heat treatment oven, is subjected to heat treatment, and is subsequently cooled.

Abstract: In a method for optimizing the joints between layers along portions of the layers which are flush with the surface of a part obtained by computer-aided modeling or prototyping involving layer decomposition, the connecting profile of two successive layers is mathematically and numerically defined using an algorithm in which the surface of the joint at the end zone adjacent to the flush portions is always substantially normal to the plane tangential to the surface of the part along the flush portions.

Abstract: Apparatus and method for controlling modeling material supply in a three-dimensional object-printing system (100). The apparatus may include one or more cartridges (180) containing modeling materials that may be connected via a set or matrix of valves (175) to the three-dimensional object printing system (100). Sensors (185) associated with the cartridges (180) may continuously or periodically monitor the status of the material within the cartridges. The controller receives data about the material presently available in each cartridge (180) and computes supply parameters for the available materials in the various cartridges (180).

Abstract: A dental device and/or process include at least one scaled and shaped linking component to be supported by a dental model or an imaging template. The process includes scaling, aligning, and orienting data from different data acquisition sources with the scaled and shaped linking component, and combining the data from different data acquisition sources into a master data file. A method of making the diagnostic model can include virtually designing an imaging template including at least one linking component made at least partially of a radio opaque material, and three-dimensionally printing the virtually designed template. The diagnostic model can include at least one of an exposed bone structure portion, a removable gum tissue portion, a removable bone structure portion, a visualization portion illustrating a root, bone density, an internal bone structure, a nerve channel, a nerve ending, a sinus cavity, a blood vessel, an artery, and diagnostic teeth.

Abstract: A generic device controller unit system (10) includes a generic “true real time” peripheral device controller and a data and protocol communications interface that uses a common set of instructions from a meta-message set. The system (10) is generic, in that the system (10) is capable of connecting a processor (40) to any number of various peripheral devices (50), instead of being designed to interconnect a processor (40) only to a specific peripheral device (50). The system (10) interfaces between a standard non-true real time operating system and peripheral devices (50) in such a manner as to employ true real time peripheral device control using the meta-message set. The device controller of the system (10) allows a standard non-true real time operating system to send instructions from the meta-message set to implement true real time control of peripheral devices (50).

Abstract: A method of three-dimensional fabrication of an object is disclosed. The method comprises: forming a plurality of layers in a configured pattern corresponding to the shape of the three-dimensional object, at least one layer of the plurality of layers being formed at a predetermined and different thickness selected so as to compensate for post-formation shrinkage of the layer along a vertical direction. In various exemplary embodiments of the invention spread of building material of one or more layers is diluted at least locally such as to maintain a predetermined thickness and a predetermined planar resolution for the layer.

Abstract: A method for manufacturing a co-molded insert part for use in composite, plastic, or metal parts is disclosed. The method comprises the step of providing a three-dimensional molding insert produced by a layer additive manufacturing process. The method further comprises the step of applying a layer material in contact with at least a portion of the molding insert. The method further comprises the step of co-molding the layer material and the molding insert simultaneously to produce a co-molded insert part.

Abstract: A modeling method for predictive modeling of a product, which may be but one example of a family of such modeling methods, includes receiving one of a processing condition of a process used to make a fibrous material into the product or a measurement of a property of the fibrous material or the tampon product, and calculating a virtual outcome from the one of the processing condition or the measurement received. The virtual outcome is one or more of not physically measured or not physically measurable, and has a relationship to the processing condition and a relationship to the measurement. The method also includes providing a measurement if the processing condition is received or a processing condition if the measurement is received, according to the virtual outcome calculated. A computing device may be programmed to carry out the method.

Abstract: The invention relates to a method of modelling a denture supply, such as a bridge construction, a crown, a cap, a set of artificial teeth or the like, said method comprising the following steps: creating or loading a first data record recording the shape of an initial situation before any treatment, such as the extraction or grinding of one or of a plurality of teeth, and creating or loading a second data record recording the shape of a post-treatment situation, and using the first and second data records for modelling the denture supply. The invention also relates to associated computer-readable data carriers and a computer.

Abstract: Solid imaging apparatus and methods for use are disclosed that reduce the amount of uncured solid imaging build material remaining on a completed build object following the completion of the solid imaging build process. The amount of uncured build material is reduced through the use of either an uncoating web that removes excess build material from the build object during the course of the building process or an ink jet source of build material that uses only as much build material as is necessary for the fabrication of the build part. Also disclosed is an imager assembly for use with such a solid imaging apparatus that incorporates two or more individual imagers in an array and accounts for variations in the intensity and alignment of adjacent imagers. The apparatus can be modified for semi-continuous operation and for integrating into a manufacturing operation, if desired.

Abstract: A system that prints three dimensional products is provided. The system includes at least one printhead for printing material to create the printed product, and an object incorporation device. The object incorporation device incorporates inorganic semiconductor objects into cavities created during the printing process.

Abstract: The systems and methods disclosed herein employ a combination of digital three-dimensional modeling and rapid fabrication technologies to provide pre-indexed, pre-registered, and/or precut components for articulated dental models. Dental articulators and components of dental models as described herein use a positioning key to encode positional information for components of the dental model, and/or a reference grid on mounting surfaces to enforce local accuracy of fabricated parts against a fixed reference array.

Abstract: A method comprising building at least one three-dimensional model and a support structure using a layer-based additive technique, where the at least one three-dimensional model is at least partially encased in the support structure, and where the support structure functions as a shipping package for the at least one three-dimensional model.

Abstract: Provided is a volume element printing system for printing a three-dimensional object. The system includes a first printhead group having a plurality of first printheads configured to print a first voxel layer on a substrate, and at least one second printhead group having a plurality of second printheads downstream from the first group. The second printhead group is configured to print a subsequent voxel layer on at least part of the first layer, said second printheads being reconfigurable as backup printheads for the first printheads in case of failure. The system also includes an object insertion device configured to insert an object into a cavity defined by the voxel layers, and a conveyor configured to convey the substrate past the printhead groups. Also included is a control system configured to control and monitor the printhead groups, the object insertion device and the conveyor, and dynamically to reconfigure the second printheads if failure of a first printhead is detected.