{"id":488,"date":"2022-05-24T11:06:07","date_gmt":"2022-05-24T11:06:07","guid":{"rendered":"https:\/\/addadditive.pt\/?page_id=488"},"modified":"2022-06-21T15:45:50","modified_gmt":"2022-06-21T15:45:50","slug":"normas","status":"publish","type":"page","link":"https:\/\/add-additive.ipleiria.pt\/en\/normas\/","title":{"rendered":"Normas"},"content":{"rendered":"\n

Biblioteca de Normas (pps5)<\/h3>\n
\n \n \n\n \n \n \n \n\n\n NORMA<\/th> ESTADO<\/th> APLICABILIDADE<\/th> RESUMO<\/th> ULTIMA ATUALIZA\u00c7\u00c3O<\/th> <\/tr>\n<\/thead>\n \n\n \n \n\n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n \n
ISO\/AWI 27548\nAdditive manufacturing of plastics \u2014 Environment, health and safety \u2014 Test method for determination of particle and chemical emission rates from desktop 3D printer material extrusion<\/td>\n 20.00 UNDER DEVELOPMENT\nPreparatory: New project registered in TC\/SC work programme<\/td>\n Pol\u00edmeros<\/td>\n This document specifies test methods to determine particle emissions (including ultrafine particles) and specified VOCs (including aldehydes) from Material Extrusion(ME) processes often used in non-industrial environments such as school, homes and office spaces in an Emission Test Chamber (ETC) under specified test conditions. However, these tests may not accurately predict real-world results. This document describes a conditioning method using an ETC with controlled temperature, humidity, air exchange rate, air velocity, and procedures for monitoring, storage, analysis, calculation, and reporting of emission rates. This document is intended to cover a Fused Filament Fabrication (FFF) type desktop 3D printer using thermoplastic materials. The primary purpose of this document is to quantify particle and chemical emission rates emitted from a specific ME type desktop 3D printer which is operated using thermoplastic feedstocks. However, not all possible emissions are covered by this method. Many feedstocks could release hazardous emissions that are not measured by the chemical detectors prescribed in this document. It is the responsibility of the user to understand the material being printed and the potential chemical emissions. An example is PVC feedstocks that could potentially emit chlorinated compounds, which would not be measured by this document.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM AWI 52953\nAdditive Manufacturing for metals \u2014 General Principles \u2014 Registration of geometric data acquired from process-monitoring and for quality control<\/td>\n 20.00 UNDER DEVELOPMENT\nPreparatory: New project registered in TC\/SC work programme<\/td>\n Metais<\/td>\n This document sets and defines the minimum requirements for registration of geometric data acquired from process-monitoring and for quality control in Additive Manufacturing (AM), including the description of a procedure. Furthermore, this document comprises actions that users need to register multi-modal AM data and store them in an appropriate repository. This document is not applicable for the following types of data: data cleansing, image processing, cost, production time and personnel. This document in only applicable for geometric data gathered and generated from non-destructive test methods and sensors by using X-ray Computer Tomography (XCT), cameras and Coordinate Measuring Machines (CMM). This document is only applicable to metals produced through means of Laser-based powder bed fusion (PBF-LB) and Direct Energy Deposition (DED). Note: The procedure can be applied to monitor other AM processes and materials (e.g. polymer or ceramic power bed fusion, binder jetting, and photopolymerization), but this document does not provide any data or case studies for them.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52925:2022\nAdditive manufacturing of polymers \u2014 Feedstock materials \u2014 Qualification of materials for laser-based powder bed fusion of parts<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Pol\u00edmeros<\/td>\n This document provides guidance and recommendations for the qualification of polymeric materials intended for laser-based powder bed fusion of polymers (PBF-LB\/P). The parameters and recommendations presented in this document relate mainly to the material polyamide 12 (PA12), but references are also made to polyamide 11 (PA11). The parameters and recommendations set forth herein cannot be applicable to other polymeric materials.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/DIS 23704-3\nGeneral requirements for cyber-physically controlled smart machine tool systems (CPSMT) \u2014 Part 3: Reference architecture of CPSMT for additive manufacturing<\/td>\n 40.60 UNDER DEVELOPMENT\nEnquiry: Close of voting<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/CD 4631\nMeasurement of the Electrochemical Localized Corrosion Potential (E-CLCP) for Biomedical Ti Alloys Fabricated via Additive Manufacturing Method<\/td>\n 30.60 UNDER DEVELOPMENT\nCommittee: Close of voting\/ comment period<\/td>\n Cer\u00e2micos<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52920\nAdditive manufacturing \u2014 Qualification principles \u2014 Quality requirements for industrial additive manufacturing sites<\/td>\n 40.99 UNDER DEVELOPMENT\nEnquiry: DIS approved for registration as FDIS<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52924\nAdditive manufacturing of polymers \u2014 Qualification principles \u2014 Classification of part properties<\/td>\n 40.99 UNDER DEVELOPMENT\nEnquiry: DIS approved for registration as FDIS<\/td>\n Pol\u00edmeros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52950:2021\nAdditive manufacturing \u2014 General principles \u2014 Overview of data processing<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document covers the principal considerations which apply to data exchange for additive manufacturing. It specifies terms and definitions which enable information to be exchanged describing geometries or parts such that they can be additively manufactured. The data exchange method outlines file type, data enclosed formatting of such data and what this can be used for.\n\nThis document\n\n\u2014 enables a suitable format for data exchange to be specified,\n\n\u2014 describes the existing developments for additive manufacturing of 3D geometries,\n\n\u2014 outlines existing file formats used as part of the existing developments, and\n\n\u2014 enables understanding of necessary features for data exchange, for adopters of this document.\n\nThis document is aimed at users and producers of additive manufacturing processes and associated software systems. It applies wherever additive processes are used, and to the following fields in particular:\n\n\u2014 producers of additive manufacturing systems and equipment including software;\n\n\u2014 software engineers involved in CAD\/CAE systems;\n\n\u2014 reverse engineering systems developers;\n\n\u2014 test bodies wishing to compare requested and actual geometries.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52921\nAdditive manufacturing \u2014 General principles \u2014 Part positioning, coordinates and orientation<\/td>\n 40.99 UNDER DEVELOPMENT\nEnquiry: DIS approved for registration as FDIS<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM PRF TR 52917\nAdditive manufacturing \u2014 Round robin testing \u2014 General guidelines<\/td>\n 50.20 UNDER DEVELOPMENT\nApproval: Proof sent to secretariat or FDIS ballot initiated: 8 weeks<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM AWI 52933\nAdditive manufacturing \u2014 Environment, health and safety \u2014 Consideration for the reduction of hazardous substances emitted during the operation of the non-industrial ME type 3D printer in workplaces, and corresponding test method<\/td>\n 20.00 UNDER DEVELOPMENT\nPreparatory: New project registered in TC\/SC work programme<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52935\nAdditive manufacturing of metals \u2013 Qualification principles \u2013 Qualification of AM coordination personnel<\/td>\n 40.00 UNDER DEVELOPMENT\nEnquiry: DIS registered<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52942:2020\nAdditive manufacturing \u2014 Qualification principles \u2014 Qualifying machine operators of laser metal powder bed fusion machines and equipment used in aerospace applications<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais<\/td>\n This document specifies requirements for the qualification of operators of laser metal powder bed fusion machines and equipment for additive manufacturing in aerospace applications.\n\nThis document is applicable if the operator qualification testing is required by contract or by application standards in the field of aerospace.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52941:2020\nAdditive manufacturing \u2014 System performance and reliability \u2014 Acceptance tests for laser metal powder-bed fusion machines for metallic materials for aerospace application<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais<\/td>\n This document specifies requirements and test methods for the qualification and re-qualification of laser beam machines for metal powder bed fusion additive manufacturing for aerospace applications.\n\nIt can also be used to verify machine features during periodic inspections or following maintenance and repair activities.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52931\nAdditive manufacturing of metals \u2014 Environment, health and safety \u2014 General principles for use of metallic materials<\/td>\n 40.99 UNDER DEVELOPMENT\nEnquiry: DIS approved for registration as FDIS<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM TR 52916:2022\nAdditive manufacturing for medical \u2014 Data \u2014 Optimized medical image data<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document includes the creation of optimized data for medical additive manufacturing (MAM). These data are generated from static modalities, such as magnetic resonance imaging (MRI), computed tomography (CT). This document addresses improved medical image data, and medical image data acquisition processing and optimization approaches for accurate solid medical models, based on real human and animal data.\n\nSolid medical models are generally created from stacked 2D images output from medical imaging systems. The accuracy of the final model depends on the resolution and accuracy of the original image data. The main factors influencing accuracy are the resolution of the image, the amount of image noise, the contrast between the tissues of interest and artefacts inherent in the imaging system.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/CD 52932\nAdditive manufacturing of polymers \u2014 Environment, health and safety \u2014 Test method for the determination of particle emission rates from desktop ME printers<\/td>\n 30.98 DELETED\nCommittee: Project deleted<\/td>\n Outros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52909\nAdditive manufacturing of metals \u2014 Finished part properties \u2014 Orientation and location dependence of mechanical properties for powder bed fusion<\/td>\n 40.99 UNDER DEVELOPMENT\nEnquiry: DIS approved for registration as FDIS<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52926-5\nAdditive Manufacturing of metals \u2014 Qualification principles \u2014 Part 5: Qualification of operators for DED-Arc<\/td>\n 40.60 UNDER DEVELOPMENT\nEnquiry: Close of voting<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52926-4\nAdditive manufacturing of metals \u2014 Qualification principles \u2014 Part 4: Qualification of machine operators for DED-LB<\/td>\n 40.60 UNDER DEVELOPMENT\nEnquiry: Close of voting<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52926-3\nAdditive manufacturing of metals \u2014 Qualification principles \u2014 Part 3: Qualification of machine operators for PBF-EB<\/td>\n 40.60 UNDER DEVELOPMENT\nEnquiry: Close of voting<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52926-2\nAdditive manufacturing of metals \u2014 Qualification principles \u2014 Part 2: Qualification of machine operators for PBF-LB<\/td>\n 40.60 UNDER DEVELOPMENT\nEnquiry: Close of voting<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52926-1\nAdditive manufacturing of metals \u2014 Qualification principles \u2014 Part 1: General qualification of machine operators<\/td>\n 40.60 UNDER DEVELOPMENT\nEnquiry: Close of voting<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM AWI 52938-1\nAdditive manufacturing of metals \u2014 Environment, health and safety \u2014 Part 1: Safety requirements for PBF-LB machines<\/td>\n 20.00 UNDER DEVELOPMENT\nPreparatory: New project registered in TC\/SC work programme<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52904:2019\nAdditive manufacturing \u2014 Process characteristics and performance \u2014 Practice for metal powder bed fusion process to meet critical applications<\/td>\n 90.92 PUBLISHED\nReview: International Standard to be revised<\/td>\n Metais<\/td>\n 1.1 This practice describes the operation and production control of metal powder bed fusion (PBF) machines and processes to meet critical applications such as commercial aerospace components and medical implants. The requirements contained herein are applicable for production components and mechanical test specimens using powder bed fusion (PBF) with both laser and electron beams.\n\n1.2 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appro-priate safety, health, and environmental practices and deter-mine the applicability of regulatory limitations prior to use.\n\n1.3 This international standard was developed in accor-dance with internationally recognized principles on standard-ization established in the Decision on Principles for the Development of International Standards, Guides and Recom-mendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52907:2019\nAdditive manufacturing \u2014 Feedstock materials \u2014 Methods to characterize metal powders<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais<\/td>\n This document provides technical specifications for metallic powders intended to be used in additive manufacturing and covers the following aspects:\n\u2014 documentation and traceability;\n\u2014 sampling;\n\u2014 particle size distribution;\n\u2014 chemical composition;\n\u2014 characteristic densities;\n\u2014 morphology;\n\u2014 flowability;\n\u2014 contamination;\n\u2014 packaging and storage.\nThis document does not deal with safety aspects.\nIn addition, this document gives specific requirements for used metallic powders in additive manufacturing.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52902:2019\nAdditive manufacturing \u2014 Test artifacts \u2014 Geometric capability assessment of additive manufacturing systems<\/td>\n 90.92 PUBLISHED\nReview: International Standard to be revised<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document covers the general description of benchmarking test piece geometries along with quantitative and qualitative measurements to be taken on the benchmarking test piece(s) to assess the performance of additive manufacturing (AM) systems.\n\nThis performance assessment can serve the following two purposes:\n\n\u2014 AM system capability evaluation;\n\n\u2014 AM system calibration.\n\nThe benchmarking test piece(s) is (are) primarily used to quantitatively assess the geometric performance of an AM system. This document describes a suite of test geometries, each designed to investigate one or more specific performance metrics and several example configurations of these geometries into test piece(s). It prescribes quantities and qualities of the test geometries to be measured but does not dictate specific measurement methods. Various user applications can require various grades of performance. This document discusses examples of feature configurations, as well as measurement uncertainty requirements, to demonstrate low and high grade examination and performance. This document does not discuss a specific procedure or machine settings for manufacturing a test piece, which are covered by ASTM F 2971 and other relevant process specific specifications.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM CD 52910\nAdditive manufacturing \u2014 Design \u2014 Requirements, guidelines and recommendations<\/td>\n 30.99 UNDER DEVELOPMENT\nCommittee: CD approved for registration as DIS<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document gives requirements, guidelines and recommendations for using additive manufacturing (AM) in product design.\n\nIt is applicable during the design of all types of products, devices, systems, components or parts that are fabricated by any type of AM system. This document helps determine which design considerations can be utilized in a design project or to take advantage of the capabilities of an AM process.\n\nGeneral guidance and identification of issues are supported, but specific design solutions and process-specific or material-specific data are not supported.\n\nThe intended audience comprises three types of users:\n\n\u2014 designers who are designing products to be fabricated in an AM system and their managers;\n\n\u2014 students who are learning mechanical design and computer-aided design; and\n\n\u2014 developers of AM design guidelines and design guidance systems.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52900:2021\nAdditive manufacturing \u2014 General principles \u2014 Fundamentals and vocabulary<\/td>\n 90.92 PUBLISHED\nReview: International Standard to be revised<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO\/ASTM 52900:2015 establishes and defines terms used in additive manufacturing (AM) technology, which applies the additive shaping principle and thereby builds physical 3D geometries by successive addition of material.\n\nThe terms have been classified into specific fields of application.\n\nNew terms emerging from the future work within ISO\/TC 261 and ASTM F42 will be included in upcoming amendments and overviews of this International Standard.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52901:2017\nAdditive manufacturing \u2014 General principles \u2014 Requirements for purchased AM parts<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO\/ASTM 52901:2017 defines and specifies requirements for purchased parts made by additive manufacturing.\n\nISO\/ASTM 52901:2017 gives guidelines for the elements to be exchanged between the customer and the part provider at the time of the order, including the customer order information, part definition data, feedstock requirements, final part characteristics and properties, inspection requirements and part acceptance methods.\n\nISO\/ASTM 52901:2017 is applicable for use as a basis to obtain parts made by additive manufacturing that meet minimum acceptance requirements. More stringent part requirements can be specified through the addition of one or more supplementary requirements at the time of the order.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO 17296-3:2014\nAdditive manufacturing \u2014 General principles \u2014 Part 3: Main characteristics and corresponding test methods<\/td>\n 90.92 PUBLISHED\nREVIEW: International Standard to be revised<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO 17296-3:2014 covers the principal requirements applied to testing of parts manufactured by additive manufacturing processes. It specifies main quality characteristics of parts, specifies appropriate test procedures, and recommends the scope and content of test and supply agreements.\n\nISO 17296-3:2014 is aimed at machine manufacturers, feedstock suppliers, machine users, part providers, and customers to facilitate the communication on main quality characteristics. It applies wherever additive manufacturing processes are used.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52915:2020\nSpecification for additive manufacturing file format (AMF) Version 1.2<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document provides the specification for the Additive Manufacturing File Format (AMF), an interchange format to address the current and future needs of additive manufacturing technology.\n\nThis document specifies the requirements for the preparation, display and transmission for the AMF. When prepared in a structured electronic format, strict adherence to an extensible markup language (XML)[1] schema supports standards-compliant interoperability.\n\nNOTE A W3C XML schema definition (XSD) for the AMF is available from ISO from http:\/\/standards.iso.org\/iso\/52915 and from ASTM from www.astm.org\/MEETINGS\/images\/amf.xsd. An implementation guide for such an XML schema is provided in Annex A.\n\nIt is recognized that there is additional information relevant to the final part that is not covered by the current version of this document. Suggested future features are listed in Annex B.\n\nThis document does not specify any explicit mechanisms for ensuring data integrity, electronic signatures and encryptions.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52903-1:2020\nAdditive manufacturing \u2014 Material extrusion-based additive manufacturing of plastic materials \u2014 Part 1: Feedstock materials<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Pol\u00edmeros<\/td>\n This document describes a method for defining requirements for plastic materials used in extrusion-based additive manufacturing (AM) processes. Materials include unfilled, filled, and reinforced plastic materials suitable for processing into parts. These materials can also contain special additives (e.g. flame retardants, stabilizers, etc.). Processes include all material extrusion-based AM processes.\n\nThis document is intended for use by manufacturers of materials, feedstocks, plastic parts or any combination of the three using material extrusion-based AM.\n\nNOTE In some cases, material manufacturers can also be feedstock manufacturers. In other cases, a material manufacturer can supply materials (example: pellets) to a feedstock manufacturer (example: converter of pellets into filaments).\n\nThis document does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety and health, and environmental practices and determine the applicability of regulatory limitations prior to use.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM CD TR 52918\nAdditive manufacturing \u2014 Data formats \u2014 File format support, ecosystem and evolutions<\/td>\n 30.00 UNDER DEVELOPMENT\nCommittee: Committee draft (CD) registered<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ----------------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM TR 52912:2020\nAdditive manufacturing \u2014 Design \u2014 Functionally graded additive manufacturing<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n The use of Additive Manufacturing (AM) enables the fabrication of geometrically complex components by accurately depositing materials in a controlled way. Technological progress in AM hardware, software, as well as the opening of new markets demand for higher flexibility and greater efficiency in today's products, encouraging research into novel materials with functionally graded and high-performance capabilities. This has been termed as Functionally Graded Additive Manufacturing (FGAM), a layer-by-layer fabrication technique that involves gradationally varying the ratio of the material organization within a component to meet an intended function. As research in this field has gained worldwide interest, the interpretations of the FGAM concept requires greater clarification. The objective of this document is to present a conceptual understanding of FGAM. The current-state of art and capabilities of FGAM technology will be reviewed alongside with its challenging technological obstacles and limitations. Here, data exchange formats and some of the recent application is evaluated, followed with recommendations on possible strategies in overcoming barriers and future directions for FGAM to take off.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM TR 52906:2022\nAdditive manufacturing \u2014 Non-destructive testing \u2014 Intentionally seeding flaws in metallic parts<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document is intended to serve as a best practice for the identification and \u201cseeding\u201d of nondestructively detectable flaw replicas of metal alloy PBF and DED processes. Three seeding categories are described:\n\na) process flaws through CAD design;\n\nb) build parameter manipulation;\n\nc) subtractive manufacturing.\n\nThese include flaws present within as-deposited materials, post heat-treated or HIP processed material, and those flaws made detectable because of post-processing operations. Geometrical aspects or measurement are not the subjects of this document.\n\nWARNING \u2014 This document does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this document to establish appropriate safety and health practices and determine the applicability of regulatory limitations prior to use.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM CD 52903-2\nAdditive manufacturing \u2014 Material extrusion-based additive manufacturing of plastic materials \u2014 Part 2: Process equipment<\/td>\n 30.98 DELETED\nCommittee: Project deleted<\/td>\n Pol\u00edmeros<\/td>\n This document describes a method for defining requirements and assuring component integrity for plastic parts created using material extrusion based additive manufacturing processes. It relates to the process, equipment and operational parameters. Processes include all material extrusion based additive manufacturing processes.\n\nThis document is intended for use by AM users and customers procuring such parts.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM CD 52903-3\nAdditive manufacturing \u2014 Standard specification for material extrusion based additive manufacturing of plastic materials \u2014 Part 3: Final parts<\/td>\n 30.98 DELETED\nCommittee: Project deleted<\/td>\n Pol\u00edmeros<\/td>\n ----------------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52911-2:2019\nAdditive manufacturing \u2014 Design \u2014 Part 2: Laser-based powder bed fusion of polymers<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Pol\u00edmeros<\/td>\n This document specifies the features of laser-based powder bed fusion of polymers (LB-PBF\/P) and provides detailed design recommendations.\n\nSome of the fundamental principles are also applicable to other additive manufacturing (AM) processes, provided that due consideration is given to process-specific features.\n\nThis document also provides a state-of-the-art review of design guidelines associated with the use of powder bed fusion (PBF) by bringing together relevant knowledge about this process and by extending the scope of ISO\/ASTM 52910.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52911-1:2019\nAdditive manufacturing \u2014 Design \u2014 Part 1: Laser-based powder bed fusion of metals<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais<\/td>\n This document specifies the features of laser-based powder bed fusion of metals (PBF-LB\/M) and provides detailed design recommendations.\n\nSome of the fundamental principles are also applicable to other additive manufacturing (AM) processes, provided that due consideration is given to process-specific features.\n\nThis document also provides a state of the art review of design guidelines associated with the use of powder bed fusion (PBF) by bringing together relevant knowledge about this process and by extending the scope of ISO\/ASTM 52910.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52911-3\nAdditive Manufacturing \u2014 Design \u2014 Part 3: Electron beam powder bed fusion of metals<\/td>\n 40.99 UNDER DEVELOPMENT\nEnquiry: DIS approved for registration as FDIS<\/td>\n Metais<\/td>\n ISO\/ASTM DIS 52911-3\nFabrico aditivo - Projeto - Parte 3: Fus\u00e3o de metais em leito de p\u00f3 de feixe de electr\u00f5es<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM TS 52930:2021\nAdditive manufacturing \u2014 Qualification principles \u2014 Installation, operation and performance (IQ\/OQ\/PQ) of PBF-LB equipment<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ----------------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52936-1\nAdditive manufacturing of polymers \u2014 Powder bed fusion \u2014 Part 1: General principles and preparation of test specimens for PBF-LB<\/td>\n 40.99 UNDER DEVELOPMENT\nEnquiry: DIS approved for registration as FDIS<\/td>\n Pol\u00edmeros<\/td>\n ----------------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO 15854:2021\nDentistry \u2014 Casting and baseplate waxes<\/td>\n 90.92 PUBLISHED\nReview: International Standard to be revised<\/td>\n Outros<\/td>\n This document specifies the classification of and requirements for dental casting and dental baseplate waxes together with the test methods to be employed to determine compliance with these requirements.\n\nThis document does not apply to waxes supplied for additive manufacturing or CAD\/CAM-based procedures.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52921:2013\nStandard terminology for additive manufacturing \u2014 Coordinate systems and test methodologies<\/td>\n 90.92 PUBLISHED\nReview: International Standard to be revised<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO\/ASTM 52921:2013 includes terms, definitions of terms, descriptions of terms, nomenclature, and acronyms associated with coordinate systems and testing methodologies for additive manufacturing (AM) technologies in an effort to standardize terminology used by AM users, producers, researchers, educators, press\/media, and others, particularly when reporting results from testing of parts made on AM systems. Terms included cover definitions for machines\/systems and their coordinate systems plus the location and orientation of parts. It is intended, where possible, to be compliant with ISO 841 and to clarify the specific adaptation of those principles to additive manufacturing.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/IEC 23510:2021\nInformation technology \u2014 3D printing and scanning \u2014 Framework for an Additive Manufacturing Service Platform (AMSP)<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ----------------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO 10303-242:2020\nIndustrial automation systems and integration \u2014 Product data representation and exchange \u2014 Part 242: Application protocol: Managed model-based 3D engineering<\/td>\n 90.92 PUBLISHED\nReview: International Standard to be revised<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document specifies the application module for AP242 managed model based 3D engineering.\n\nThe following are within the scope of this document:\n\nproducts of automotive, aerospace and other mechanical manufacturers and of their suppliers, including parts, assemblies of parts, tools, assemblies of tools, and raw materials;\nengineering and product data for the purpose of long-term archiving and retrieval;\nproduct data management\nbreakdown data representing a parent-child structures, such as functional, physical, system or zonal breakdowns. A breakdown is made of breakdown element;\nproduct definition data and configuration control data for managing large numbers of variants of products during the design phase;\ndata describing the changes that have occurred during the design phase, including tracking of the versions of a product and of the data related to the documentation of the change process;\ndelta change: data describing the exchange of differences with respect to a set of data previously sent;\nidentification of standard parts, based on international, national, or industrial standards;\nrelease and approval data for product data;\ndata that identify the supplier of a product and related contract information;\nproperties of parts or of tools;\nreferences to product documentation represented in a format other than those specified by ISO 10303;\nproduct manufacturing information, covering the design and manufacturing planning phase;\nidentification of physically realized parts or of tools, including assembly of physically realized products and recording of test results.\nprocess planning\nprocess plan information describing the relationships between parts and the tools used to manufacture them and to manage the relationships between intermediate stages of part or tool development.\nmechanical design\ndifferent types of geometry models, including:\n2D- and 3D-wireframe geometry model;\ngeometrically bounded surface geometry model;\ntopologically bounded surface geometry model;\nfaceted-boundary geometry model;\nboundary geometry model;\ncompound shape geometry model;\nconstructive solid geometry model;\nparametric and constrained geometry model;\n2D-sketch model;\n3D tessellated geometry model;\n3D scan data;\ncurved triangles.\nrepresentation of the shape of parts or tools that is a combination of two or more of different types of geometry models;\ndata that pertains to the presentation of the shape of the product;\nrepresentation of portions of the shape of a part or a tool by manufacturing features;\ndata defining surface conditions;\ndimensional and geometrical tolerance data;\nquality criteria and inspection results of given three dimensional product shape data;\nproduct documentation as annotated 3D models and as drawings.\nmessage\ndata that identify a message and an envelope.\ninterface\ndata representing the interfaces with version management mechanism and the definition of connection with connectors.\nmating\ndata representing the detailed assembly information on how the involved part occurrences are mated together and which constraints apply.\nkinematics\nsimulation data for the description of kinematic structures and motion.\nanalysis management\ndata representing an analysis, managed in versions and the link to the result of the analysis.\ncomposite design\ndefinition of composite structural parts;\nthe association of the constituents of composite and metallic parts with the constituent shape model;\nthe depiction of composite laminate tables describing the material, stacking sequence and ply orientation;\nconstituents of the composite or a portion of the composite with a defined shape;\nthe identification of material specifications from internal and external sources and their properties for a specific operating environment.\nelectrical harness assembly design\nelectrical wire harnesses design;\nphysical electrical harness model for design and construction;\nelectrical connectivity information in multilevel assemblies;\nwire and cable list data;\ndefinition of wire, cable and connector features.\nadditive manufacturing part design\nbuild information.\nrequirements management\nverification and validation.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/TS 10303-1835:2019\nIndustrial automation systems and integration \u2014 Product data representation and exchange \u2014 Part 1835: Application module: Additive manufacturing part and build information<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO\/TS 10303-1835:2019 specifies the application module for Additive manufacturing part and build information.\n\nThe following are within the scope of ISO\/TS 10303-1835:2019:\n\nadditive manufacturing process that use a single build direction perpendicular to a planar build plate;\nidentification of the additive manufacturing build plate;\ndefinition of the part build orientation and placement on the build plate;\ndefinition of the available build volume of the additive manufacturing machine as a bounding box;\nproviding mechanism to distinguish between the support structure geometry and the part geometry.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO 14649-17:2020\nIndustrial automation systems and integration \u2014 Physical device control \u2014 Data model for computerized numerical controllers \u2014 Part 17: Process data for additive manufacturing<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document specifies the process data for additive manufacturing. This document describes additive manufacturing at the micro process plan level without making a commitment to particular machines, processes or technologies.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO 22910:2020\nCorrosion of metals and alloys \u2014 Measurement of the electrochemical critical localized corrosion temperature (E-CLCT) for Ti alloys fabricated via the additive manufacturing method<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Cer\u00e2micos<\/td>\n This document specifies procedures for testing the resistance to localized corrosion of Ti alloys fabricated via additive manufacturing (AM) method. This document regulates the electrochemical critical localized corrosion temperature (E-CLCT) of the AM Ti materials for a comparative evaluation of resistance to localized corrosion.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO 28219:2017\nPackaging \u2014 Labelling and direct product marking with linear bar code and two-dimensional symbols<\/td>\n 60.60 PUBLISHED\nInternational Standart published<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO 28219:2017\n\n- defines minimum requirements for identifying items,\n- provides guidelines for item marking with machine-readable symbols,\n- covers both labels and direct marking of items,\n- includes testing procedures for label adhesive characteristics and mark durability,\n- provides guidance for the formatting on the label of data presented in linear bar code, two-dimensional symbol or human-readable form,\n- is intended for applications which include, but are not limited to, support of systems that automate the control of items during the processes of:\n- production,\n- inventory,\n- distribution,\n- field service,\n- point of sale,\n- point of care,\n- repair, and\n- is intended to include, but it is not limited to, multiple industries including:\n- automotive,\n- aerospace,\n- chemical,\n- consumer items,\n- electronics,\n- health care,\n- marine,\n- rail,\n- telecommunications.\nThe location and application method of the marking are not defined (these will be reviewed and agreed upon by suppliers and manufacturers and their trading partners before implementing ISO 28219:2017).\nISO 28219:2017 does not supersede or replace any applicable safety or regulatory marking or labelling requirements. ISO 28219:2017 is meant to satisfy the minimum item marking requirements of numerous applications and industry groups and as such its applicability is to a wide range of industries, each of which may have specific implementation guidelines for it. ISO 28219:2017 is to be applied in addition to any other mandated labelling direct-marking requirements.\nThe labelling and direct marking requirement of ISO 28219:2017 and other standards can be combined into one label or marking area or appear as separate labels or marking areas.\nISO 28219:2017 uses the terms \"part marking\" and \"item marking\" interchangeably. Unless otherwise stated, ISO 28219:2017 will use the term \"item marking\" to describe both the labelling and direct part marking (DPM) of an item, where DPM includes, but is not limited to, altering (e.g. dot peen, laser etch, chemical etch), as well as additive type processes (e.g. ink jet, vacuum deposition).\nThe purpose of ISO 28219:2017 is to establish the machine-readable (linear, two-dimensional, and composite symbols) and human-readable content for direct marking and labelling of items, parts, and components.\nISO 28219:2017 provides a means for items, parts and components to be marked, and read in either fixtured or hand-held scanning environments at any manufacturer's facility and then read by customers purchasing items for subsequent manufacturing operations or for final end use. Intended applications include, but are not limited to, supply chain applications, e.g. inventory, distribution, manufacturing, quality control, acquisition, transportation, supply, repair, and disposal.\nThe figures are illustrative and not necessarily to scale or to the quality requirements specified in ISO 28219:2017.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/TS 10303-442:2019\nIndustrial automation systems and integration \u2014 Product data representation and exchange \u2014 Part 442: Application module: AP242 managed model based 3D engineering<\/td>\n 90.92 PUBLISHED\nReview: International Standard to be revised<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO\/TS 10303-442:2019 specifies the application module for AP242 managed model based 3D engineering.\n\nThe following are within the scope of ISO\/TS 10303-442:2019:\n\nproducts of automotive, aerospace and other mechanical manufacturers and of their suppliers, including parts, assemblies of parts, tools, assemblies of tools, and raw materials;\nengineering and product data for the purpose of long-term archiving and retrieval;\nproduct data management\nbreakdown data representing a parent-child structures, such as functional, physical, system or zonal breakdowns. A breakdown is made of breakdown element;\nproduct definition data and configuration control data for managing large numbers of variants of products during the design phase;\ndata describing the changes that have occurred during the design phase, including tracking of the versions of a product and of the data related to the documentation of the change process;\ndelta change: data describing the exchange of differences with respect to a set of data previously sent;\nidentification of standard parts, based on international, national, or industrial standards;\nrelease and approval data for product data;\ndata that identify the supplier of a product and related contract information;\nproperties of parts or of tools;\nreferences to product documentation represented in a format other than those specified by ISO 10303;\nproduct manufacturing information, covering the design and manufacturing planning phase;\nidentification of physically realized parts or of tools, including assembly of physically realized products and recording of test results.\nprocess planning\nprocess plan information describing the relationships between parts and the tools used to manufacture them and to manage the relationships between intermediate stages of part or tool development.\nmechanical design\ndifferent types of geometry models, including:\n2D- and 3D-wireframe geometry model;\ngeometrically bounded surface geometry model;\ntopologically bounded surface geometry model;\nfaceted-boundary geometry model;\nboundary geometry model;\ncompound shape geometry model;\nconstructive solid geometry model;\nparametric and constrained geometry model;\n2D-sketch model;\n3D tessellated geometry model;\n3D scan data;\ncurved triangles.\nrepresentation of the shape of parts or tools that is a combination of two or more of different types of geometry models;\ndata that pertains to the presentation of the shape of the product;\nrepresentation of portions of the shape of a part or a tool by manufacturing features;\ndata defining surface conditions;\ndimensional and geometrical tolerance data;\nquality criteria and inspection results of given three dimensional product shape data;\nproduct documentation as annotated 3D models and as drawings.\nmessage\ndata that identify a message and an envelope.\ninterface\ndata representing the interfaces with version management mechanism and the definition of connection with connectors.\nmating\ndata representing the detailed assembly information on how the involved part occurrences are mated together and which constraints apply.\nkinematics\nsimulation data for the description of kinematic structures and motion.\nanalysis management\ndata representing an analysis, managed in versions and the link to the result of the analysis.\ncomposite design\ndefinition of composite structural parts;\nthe association of the constituents of composite and metallic parts with the constituent shape model;\nthe depiction of composite laminate tables describing the material, stacking sequence and ply orientation;\nconstituents of the composite or a portion of the composite with a defined shape;\nthe identification of material specifications from internal and external sources and their properties for a specific operating environment.\nelectrical harness assembly design\nelectrical wire harnesses design;\nphysical electrical harness model for design and construction;\nelectrical connectivity information in multilevel assemblies;\nwire and cable list data;\ndefinition of wire, cable and connector features.\nadditive manufacturing part design\nbuild information.\nrequirements management\nverification and validation.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52927\nAdditive manufacturing \u2014 General principles \u2014 Main characteristics and corresponding test methods<\/td>\n 40.60 UNDER DEVELOPMENT\nEnquiry: Close of voting<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n <\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DIS 52908\nAdditive manufacturing of metals \u2014 Finished Part properties \u2014 Post-processing, inspection and testing of parts produced by powder bed fusion<\/td>\n 40.99 UNDER DEVELOPMENT\nEnquiry: DIS approved for registration as FDIS<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM WD 52937\nAdditive Manufacturing of metals \u2014 Qualification principles \u2014 Qualification of designers<\/td>\n 20.98 DELETED\nPreparatory: Project deleted<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n <\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM CD 52928\nAdditive manufacturing \u2014 Feedstock materials \u2014 Powder life cycle management<\/td>\n 30.99 UNDER DEVELOPMENT\nCommittee: CD approved for registration as DIS<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n <\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO 17296-2:2015\nAdditive manufacturing \u2014 General principles \u2014 Part 2: Overview of process categories and feedstock<\/td>\n 90.93 PUBLISHED\nReview: International Standard confirmed<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO 17296-2:2015 describes the process fundamentals of Additive Manufacturing (AM). It also gives an overview of existing process categories, which are not and cannot be exhaustive due to the development of new technologies. ISO 17296-2:2015 explains how different process categories make use of different types of materials to shape a product's geometry. It also describes which type of material is used in different process categories. Specification of feedstock material and requirements for the parts produced by combinations of different processes and feedstock material will be given in subsequent separate standards and are therefore not covered by ISO 17296-2:2015. ISO 17296-2:2015 describes the overreaching principles of these subsequent standards.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DTR 52905\nAdditive manufacturing of metals \u2014 Non-destructive testing and evaluation \u2014 Defect detection in parts<\/td>\n 30.98 DELETED\nCommittee: Project deleted<\/td>\n Metais<\/td>\n <\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DTR 52913-1\nAdditive manufacturing \u2014 Feedstock materials \u2014 Part 1: Parameters for characterization of powder flow properties<\/td>\n 30.92 UNDER DEVELOPMENT\nCommittee - CD referred back to Working Group<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n <\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO 17296-4:2014\nAdditive manufacturing \u2014 General principles \u2014 Part 4: Overview of data processing<\/td>\n 95.99 WITHDRAWAL\nWithdrawal of International Standard<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO 17296-4:2014 covers the principal considerations which apply to data exchange for additive manufacturing. It specifies terms and definitions which enable information to be exchanged describing geometries or parts such that they can be additively manufactured. The data exchange method outlines file type, data enclosed formatting of such data and what this can be used for.\n\nISO 17296-4:2014 enables a suitable format for data exchange to be specified, describes the existing developments for additive manufacturing of 3D geometries, outlines existing file formats used as part of the existing developments, and enables understanding of necessary features for data exchange for adopters of the International Standard.\n\nISO 17296-4:2014 is aimed at users and producers of additive manufacturing processes and associated software systems. It applies wherever additive processes are used, and to the following fields in particular: production of additive manufacturing systems and equipment including software; software engineers involved in CAD\/CAE systems; reverse engineering systems developers; test bodies wishing to compare requested and actual geometries.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM CD 52904\nAdditive manufacturing of metals \u2014 Process characteristics and performance \u2014 Metal powder bed fusion process to meet critical applications<\/td>\n 30.99 UNDER DEVELOPMENT\nCommittee: CD approved for registration as DIS<\/td>\n Metais<\/td>\n 1.1 This practice describes the operation and production control of metal powder bed fusion (PBF) machines and processes to meet critical applications such as commercial aerospace components and medical implants. The requirements contained herein are applicable for production components and mechanical test specimens using powder bed fusion (PBF) with both laser and electron beams.\n\n1.2 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appro-priate safety, health, and environmental practices and deter-mine the applicability of regulatory limitations prior to use.\n\n1.3 This international standard was developed in accor-dance with internationally recognized principles on standard-ization established in the Decision on Principles for the Development of International Standards, Guides and Recom-mendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52910:2018\nAdditive manufacturing \u2014 Design \u2014 Requirements, guidelines and recommendations<\/td>\n 90.92 PUBLISHED\nReview: International Standard to be revised<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n This document gives requirements, guidelines and recommendations for using additive manufacturing (AM) in product design.\n\nIt is applicable during the design of all types of products, devices, systems, components or parts that are fabricated by any type of AM system. This document helps determine which design considerations can be utilized in a design project or to take advantage of the capabilities of an AM process.\n\nGeneral guidance and identification of issues are supported, but specific design solutions and process-specific or material-specific data are not supported.\n\nThe intended audience comprises three types of users:\n\n\u2014 designers who are designing products to be fabricated in an AM system and their managers;\n\n\u2014 students who are learning mechanical design and computer-aided design; and\n\n\u2014 developers of AM design guidelines and design guidance systems.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM 52903-2:2020\nAdditive manufacturing \u2014 Material extrusion-based additive manufacturing of plastic materials \u2014 Part 2: Process equipment<\/td>\n 90.93 PUBLISHED\nReview: International Standard confirmed<\/td>\n Pol\u00edmeros<\/td>\n This document describes a method for defining requirements and assuring component integrity for plastic parts created using material extrusion based additive manufacturing processes. It relates to the process, equipment and operational parameters. Processes include all material extrusion based additive manufacturing processes.\n\nThis document is intended for use by AM users and customers procuring such parts.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/CD 5425\nSpecifications for use of poly(lactic acid) based filament in additive manufacturing applications<\/td>\n 30.60 UNDER DEVELOPMENT\nCommittee: Close of voting\/ comment period<\/td>\n Metais; Cer\u00e2micos; Pol\u00edmeros<\/td>\n ISO \/ CD 5425\nEspecifica\u00e7\u00f5es para uso de filamento \u00e0 base de poli (\u00e1cido l\u00e1tico) em aplica\u00e7\u00f5es de Fabrico aditivo<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM DTR 52952\nAdditive Manufacturing of metals \u2014 Feedstock materials \u2014 Correlating of rotating drum measurement with powder spreadability in PBF-LB machines<\/td>\n 30.99 UNDER DEVELOPMENT\nCommittee: CD approved for registration as DIS<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM AWI 52945\nAdditive manufacturing for Automotive \u2014 Qualification principles \u2014 Generic machine evaluation and specification of Key Performance Indicators for PBF-LB\/M processes<\/td>\n 40.00 UNDER DEVELOPMENT\nEnquiry: DIS registered<\/td>\n Metais<\/td>\n This document defines the methodology for generic AM-machine evaluation in automotive environment using objective test criteria and provides the framework for an objective AMmachine evaluation and comparison. This document finds application in benchmarks, preparation of purchase decisions, but also AM-machine evaluation within the machine procurement, acceptance, and qualification process. The methodology and performance characteristics are introduced to enable evaluation on an objective and quantitative basis. The documentation resulting from the AM-machine evaluation is used to obtain a reliable orientation selection and evaluation of PBF-LB\/M AM-machines. Furthermore, this document specifies machine KPIs in the context of machine procurement, production planning and production of PBF-LB\/M components. It aims to reach a detailed understanding between machine supplier and machine customer with respect to the acceptance criteria during the procurement process and evaluation of machine performance during running production. This document is applicable to the additive manufacturing technology LPBF-M defined in ISO\/ASTM 52900.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM CD 52939\nAdditive Manufacturing for construction \u2014 Qualification principles \u2014 Structural and infrastructure elements<\/td>\n 30.99 UNDER DEVELOPMENT\nCommittee: CD approved for registration as DIS<\/td>\n Outros<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM AWI 52908\nAdditive manufacturing \u2014 Post-processing methods \u2014 Standard specification for quality assurance and post processing of powder bed fusion metallic parts<\/td>\n 20.98 DELETED\nPreparatory: Project deleted<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM AWI 52943-2\nAdditive manufacturing for aerospace \u2014 Process characteristics and performance \u2014 Part 2: Directed energy deposition using wire and arc<\/td>\n 30.20 UNDER DEVELOPMENT\nCommittee: CD study\/ballot initiated<\/td>\n Outros<\/td>\n This document specifies requirements for the additive manufacturing of metallic parts with directed energy deposition in the aerospace industry. These can be additively generated parts or additively generated additions to existing parts. Within the application scope of this document, wire is used as feedstock, and arc processes (gas-shielded metal arc processes, Tungsten inert gas processes, plasma arc processes) are the main energy source. This document is to be used in conjunction with the engineering documents, if required by the engineering authority.<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM WD 52919-2\nAdditive manufacturing \u2014 Qualification principles \u2014 Part 2: Physical properties of sand mold for metalcasting<\/td>\n 20.98 DELETED\nPreparatory: Project deleted<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n
ISO\/ASTM WD 52919-1\nAdditive manufacturing \u2014 Qualification principles \u2014 Part 1: Mechanical properties of sand mold for metalcasting<\/td>\n 20.98 DELETED\nPreparatory: Project deleted<\/td>\n Metais<\/td>\n -------<\/td>\n 01\/01\/1970<\/td>\n <\/tr>\n <\/tbody> \n\n \n <\/table>\n\n Generated by wpDataTables<\/a><\/span>\n<\/div>