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EOSINT M 270 builds metal parts using Direct Metal Laser-Sintering (DMLS). The technology fuses metal powder into a solid part by melting it locally using a focussed laser beam. The parts are built up additively layer by layer. Even highly complex geometries are created directly from 3D CAD data, fully automatically, in just a few hours and without any tooling. It is a net-shape process, producing parts with high accuracy and detail resolution, good surface quality and excellent mechanical properties.
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The EOSINT P 730 is an advancement of the EOSINT P 700, the world-wide first double-laser system for laser-sintering of plastics. It is one of the largest plastic laser-sintering systems available on the market. The EOSINT P 730 is up to 40 percent more productive compared to the EOSINT P 700 and combines increased productivity with highest part quality. IntelliScan 20, a digital scanner of the latest generation, exposes the respective layers in a so-far unknown speed and stands for highest precision. The system is ideally suited for the economic production of small series and individualised products, especially with complex geometries. At the same time it provides capacity for the fast and flexible creation of prototypes or patterns for investment and vacuum casting. Within a very short time, the machine also produces large and complex plastic products or castings. These often occur in the automotive, medical and aerospace industry.
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The EOSINT S 750 is the only double laser-sintering system world-wide for the processing of Croning moulding material. Using the DirectCast method, the system builds cores and moulds for sand casting. Directly from CAD data, fully automatically, with a building speed of up to 2,500 cm3/h (0.09 ft3/h.) and without any tooling. Sand parts of any complexity are built layer by layer, with high accuracy, detail resolution and surface quality. The maximum part size adds up to 720 mm x 380 mm x 380 mm (28.4 x 15 x 15 in.). The resulting cores or core packages are realized with significant savings in time and costs compared to conventional technologies. Usually they also consist of less parts which are thus assembled faster and more precisely.
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PXS Dental puts forward a rapid manufacturing solution for fixed prostheses using laser sintering directly usable by dental laboratories.
This new system enables dental laboratories to access to a technology until now restricted to production centers.
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PM100T Dental is the first rapid manufacturing system using laser sintering of powder developped for production centers of dental prostheses.
It enables to produce directly by addition of material and without tooling crowns, capes and bridges up to 16 elements.
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EOSINT M 270 builds metal parts using Direct Metal Laser-Sintering (DMLS). The technology fuses metal powder into a solid part by melting it locally using a focussed laser beam. The parts are built up additively layer by layer. Even highly complex geometries are created directly from 3D CAD data, fully automatically, in just a few hours and without any tooling. It is a net-shape process, producing parts with high accuracy and detail resolution, good surface quality and excellent mechanical properties.
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LENS is an inherently more efficient approach that reduces production costs and speeds time to market for high-value components. In addition to economic advantages, the LENS system enables the fabrication of novel shapes, hollow structures, and material gradients that are not otherwise feasible. LENS can even be used to add features to cast or forged parts.
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PM250 is a prototyping and rapid manufacturing system using laser sintering adjustable metal-ceramics.
It makes available to the users a parametrable system with multiple setting ranges tapping into the full potential of metallurgy.
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The PM100T system is the first laser sintering equipment adapted for the industrialists who mainly manufacture small parts.
- Use of standard fine powders
- Customizable layering system
- High reliable fiber laser
- Integrated CAD/CAM
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Specially dedicated to rapid manufacturing of metal parts, PXL system represents a new step of development of « Phenix » laser sintering process. This new equipment is focusing on productivity, liability, ergonomics and safety to be perfectly adapted to an industrial environment.
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Choose the solid imaging solution trusted the world over. Leading manufacturers - BMW, Boeing, NASA, Reebok - and service bureaus throughout the world count on our SLS® systems to quickly produce three-dimensional prototypes, parts, molds, tools, and casting patterns.
Create parts and physical prototypes fast - by skipping the tooling step. The SLS system and materials enable you to create durable, metal, plastic, or rubber-like parts directly from any solid CAD model in as little as one day - and without dependence on costly tooling or skilled labor.
Beat your competition to market. With the SLS system your product development team can create better products in less time. Create complex tooling inserts that are ready to use in days, not weeks. Test parts for form, fit, and function off working prototypes - and identify errors early in the design process, prior to manufacturing. And count on 3D Systems for the training, support, and solid imaging solutions you need to tackle any application.
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EOSINT P 390 offers economical solutions for a broad range of applications. It is a highly productive system for processing thermoplastics. The machine manufactures plastic products of any complexity from polyamide or polystyrene materials directly from CAD data and within a very short time. Especially for individualized products or for products with complex geometries the machine unleashes its full potential. IntelliScan 20, a digital scanner of the latest generation, exposes the respective layers in a so-far unknown speed and stands for highest precision.
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LENS 750 system is designed for rapid manufacturing of metal components in state-of-the-art materials such as titanium, stainless steel, and Inconel®. The LENS 750 system offers a 300 mm cubed work envelope, making it ideal for the manufacture or repair of smaller components. LENS systems use energy from a high-power laser to build up structures one layer at a time directly from powdered metals. The resulting fully functional three-dimensional components have mechanical properties that can be equivalent or even superior to wrought materials. LENS systems can be used throughout the entire product lifecycle for applications ranging from functional prototyping to rapid manufacturing or repair.
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Precision Photonics offers superior quality mirrors and coatings at a great value. We use only ion-beam-sputtered (IBS) coatings because IBS coatings are significantly more dense, durable, and rugged than conventional e-beam or ion-assisted evaporated coatings. Compared to other coatings, IBS coatings also offer lower scatter and absorption losses and fewer pin-hole defects in the coated surface. This superior film quality and uniformity results in environmentally stable optics with laser damage thresholds of >40 joules at 1064nm.
The SBB super broadband mirrors are ideal for beam-steering applications using both the fundamental laser wavelength and one or more harmonics within the same beam path. Because it is an all-dielectric design, they can handle the high laser powers of both CW and pulsed systems, without limiting the useful angle of incidence or sensitivity to varying states of polarization.
The MPM mirror has been specially designed for multi-photon applications requiring high reflectivity, broad bandwidth, low dispersion and high transmission in the visible spectrum. All our laser mirrors are ion beam sputtered; thus the coatings are dense, easy to clean and insensitive to moisture.
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These laser mirrors are designed for specific wavelength laser applications where low wavefront distortion, low scattering, and high reflectivity are usually important. The reflectance is greater than 99.5% at the specified wavelength. Typically the s-polarization is greater than 99.9% and p-polarization is close to 99.5%.
Possible surface damage from higher power laser beams is minimized by careful polishing and precisely controlled coating methods.
As with the broadband mirrors, standard diameters are 1/2 inch, 3/4 inch, 1 inch and 2 inches. Other diameters are available on request. Other laser wavelengths can also be provided so please call.
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Research Electro-Optics, Inc. (REO) produces laser components with the highest performance and greatest reliability worldwide utilizing its superior optical fabrication, superpolishing, and precision thin film coating capabilities. REO manufactures high reflector mirrors, output couplers, beam steering optics, edge filters and Brewster windows which offer the best available performance in terms of scatter, absorption, spectral characteristics, stability, laser damage threshold, and plasma durability.
Features
Superpolished Substrates
Plano and Spherical Optics (1 cm to infinity radius of curvature)
Ultra Low Scatter & Absorption (as little as 1part per million)
Ultra High Laser Damage Thresholds
Ion Beam Sputtered Coatings
Mirrors with Extremely High Reflectivity (up to 99.999%)
Extremely High Ultraviolet and Plasma Durability
High Moisture and Temperature Stabilities
Applications
Lasers (244 nm - 3.39um)
Inter Cavity Optics
Frequency Reference Cavities
Optical Instrumentation
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Optida Co. design and produce various configuration laser optical components like High-Reflection Laser Mirrors. Components could be optimized for any coupling and rezonating wavelengths.
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MDG mirror series was designed to meet any protection need when it is necessary to realize a perimetrical protection.
It is possible to use them with every SB4/SB2 safety barrier. Thanks to the easy installation and excellent performances, this product is extremely versatile and suites the varied applications. This mirror series was born to meet any protection need it is necessary to realize a perimetrical protection.
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Mirrors are available in a variety of sizes and shapes. In addition to shape and dimensions, the primary factors that need to be considered when specifying a mirror are: the reflective coating, the substrate material, the flatness or surface accuracy, cosmetic surface quality.
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