On December 13, the Ministry of Industry and Information Technology issued the "Notice on Printing and Distributing the Additive Manufacturing Industry Development Action Plan (2017-2020)" (hereinafter referred to as the "Notice").

The "Notice" clearly states that the Ministry of Industry and Information Technology, the Ministry of Development and Reform, the Ministry of Education, the Ministry of Public Security, the Ministry of Finance, the Ministry of Commerce, the Ministry of Culture, the Health and Family Planning Commission, the General Administration of Customs, the General Administration of Quality Supervision, Inspection and Quarantine, and the Intellectual Property Office jointly The Additive Manufacturing Industry Development Action Plan (2017-2020) (hereinafter referred to as the "Plan").

The "Notice" listed "3D printing + medical " content as one of the key tasks. For the needs of personalized medical devices (including medical non-medical devices), rehabilitation devices, implants, soft tissue repair, and new drug development in the medical field, we will promote the improvement of personalized medical additive manufacturing products in classification, clinical testing, registration, and market access. Other aspects of the policy and regulations, research and determine the medical service project fee standards and medical insurance support standards for medical additive manufacturing products and services.

Additive Manufacturing Industry Development Action Plan

(2017-2020)

Additive manufacturing (also known as 3D printing) is an emerging manufacturing technology that builds out physical materials on a layer-by-layer basis based on a digital model. It will have a profound impact on traditional process, production line, factory model, and industrial chain combination. A representative subversive technology in manufacturing. China attaches great importance to the additive manufacturing industry and regards it as the development focus of "Made in China 2025". In 2015, the Ministry of Industry and Information Technology, the Development and Reform Commission, and the Ministry of Finance jointly issued the “National Additive Manufacturing Industry Development Promotion Plan (2015-2016)”. Through policy guidance, with the joint efforts of all sectors of society, China’s additive manufacturing The key technologies continued to break through, the equipment performance was significantly improved, the application fields were expanding, and the ecosystem was initially formed. A number of backbone enterprises with certain competitiveness emerged, forming a number of industrial clusters, and the additive manufacturing industry achieved rapid development.

At present, a new round of scientific and technological revolution and industrial revolution are emerging around the world. All countries in the world have taken additive manufacturing as a new growth point for future industrial development, and promoted the acceleration of additive manufacturing technology and information network technology, new material technology and new design concepts. Fusion. The global manufacturing and consumption model has begun to reshape, and the additive manufacturing industry will usher in tremendous development opportunities. Compared with developed countries, China's additive manufacturing industry still has problems such as the lag of key technologies, insufficient innovation capability, the high-quality reliability of high-end equipment and parts, and the need to improve the breadth of applications. In order to effectively link the “National Additive Manufacturing Industry Development Promotion Plan (2015-2016)”, we should cope with the new situation, new opportunities and new demands of the additive manufacturing industry, and promote the rapid, healthy and sustainable development of China's additive manufacturing industry. .

Action goal

By 2020, the annual sales revenue of the additive manufacturing industry will exceed 20 billion yuan, with an average annual growth rate of over 30%. The key core technologies have reached the international synchronous development level, the process equipment has basically met the industrial application requirements, the ecological system construction has been remarkably improved, and the scale application has been realized in some areas, and the international development capability has been significantly improved.

The technical level has improved significantly. Break through more than 100 key industries to apply urgently needed process equipment, core components and special materials, and greatly improve the quality and supply capacity of additive manufacturing products. The key core technologies of important links in the industrial chain, such as special materials and process equipment, have developed in parallel with the international market, and some areas have reached the international advanced level.

Industry applications have significantly deepened. Carry out more than 100 pilot demonstration projects with wide application scope and remarkable implementation effects, and cultivate a number of demonstration enterprises and parks with outstanding innovation capabilities and distinctive features to promote additive manufacturing in aviation, aerospace, shipbuilding, automobile, medical, culture and education. And other areas to achieve scaled applications.

The ecological system is basically perfect. Nurturing and forming a complete additive manufacturing industry chain from materials, processes, software, core devices to equipment, covering the additive manufacturing ecosystem including measurement, standards, testing, and certification. A number of public service platforms have been built to form a number of industrial clusters.

The global layout was initially implemented. Coordinate the use of international and domestic resources to form a diversified and in-depth cooperation model from technology research and development, manufacturing, capital operation, marketing to brand building, and cultivate more than 2-3 leading enterprises with strong international competitiveness. Create 2-3 well-known brands with international influence and promote a batch of technologies, equipment, products and standards to successfully enter the international market.

Key task

Box 1 Improve the quality of special materials for additive manufacturing

Metal additive manufacturing materials. Research on metal spherical powder forming and preparation technology, break through high-speed rotary electrode milling, gas atomization and other equipment, and develop high-quality titanium alloys and high-temperature alloys with low hollow powder ratio, regular particle shape, uniform particle size and low impurity element content. Metal powder such as aluminum alloy. Research on special liquid metal materials for additive manufacturing.

Inorganic non-metallic additive manufacturing materials. Study ceramic powder, zirconia, silicon carbide, aluminum nitride, silicon nitride and other ceramic powder, sheet preparation methods to improve material yield and performance consistency.

Organic polymer additive manufacturing materials. Break through heat conduction, interfacial chain entanglement and performance control technology in material systems such as additive-made resin and ultra-high molecular weight polymer, and develop high-performance and stable additive-made photosensitive resin, binder, catalyst, and wax material. Performance anti-aging engineering plastics and elastomers.

Bio-additive manufacturing materials. Establish a bio-additive manufacturing material system, continuously improve the biological properties of implantable materials and additive manufacturing process performance, improve the material design and microstructure design technology of personalized medical devices, and develop organ/tissue simulation materials with different degrees of hardness and hardness. Develop biological "ink" to meet different needs.

Box 2 Enhance the quality of additive manufacturing equipment, core components and software

Metal material additive manufacturing equipment. Improve the quality and reliability of laser/electron beam high-efficiency selection melting, large-scale integral component laser and electron beam powder feeding/wire feeding deposition, liquid metal inkjet printing and other additive manufacturing equipment.

Non-metallic materials additive manufacturing equipment. Improve the quality performance and reliability of additive manufacturing equipment such as photocuring, fused deposition, laser selective sintering, moldless casting and material injection molding.

Biomaterial additive manufacturing equipment. Improve the quality performance and reliability of additive manufacturing equipment such as bionic tissue repair scaffolds, medical personalization, cell active materials, organ microstructures and functional analog chips.

Core devices and software. Improve high beam quality laser and beam shaping system, high quality electron gun and high speed scanning system, high power laser scanning galvanometer, dynamic focusing mirror and other precision optics, high precision array nozzle print head / nozzle, processor, memory, industrial control Device quality performance of devices, high-precision sensors, digital-to-analog analog converters, etc. Break through data design software, data processing software, process library, process analysis and process intelligent planning software, online detection and monitoring system and forming process intelligent control software and other additive manufacturing core support software.

Box 3 Demonstration applications in key manufacturing areas

Promote the demonstration application of additive manufacturing in key manufacturing fields such as aviation, aerospace, shipbuilding, nuclear industry, automobiles, power equipment, rail transit equipment, home appliances, molds, and casting.

Aviation: Advance laser direct deposition, electron beam fuse forming technology for titanium alloy frames, beams, ribs, lips, integral leaf discs, casings and ultra-high-strength steels for large-scale and complex structural parts of various aircraft platforms and engines. Application of bearing members such as structural members, advancing the demonstration application of laser and electron beam selective melting technology on protective grids, fuel nozzles and turbine blades, and strengthening additive manufacturing technology for titanium alloy frame and integral leaf disc key structure Verification study of repairs.

Aerospace: The use of additive manufacturing technology to achieve rapid design and prototyping of powertrains, complex components such as launch vehicles, satellites, deep space probes, and direct manufacturing and repair of consumable parts and spare parts.

Ships: Advance additive manufacturing in the field of shipbuilding and ancillary equipment, product development, structural optimization, process development, online repair and other applied research, to achieve rapid design and optimization of ships and complex parts, to promote power system, deck and cabin machinery and other key zeros Direct manufacturing of components and spare parts.

Nuclear industry: Advance additive manufacturing in nuclear-level equipment complex, key component product development, process testing, testing and certification, using additive manufacturing technology to promote online repair of in-service nuclear facilities.

Automobile: In the new product design and trial production stage, the additive manufacturing technology is used to realize the moldless design and manufacture, and the development cycle is shortened. Integrated manufacturing with additive manufacturing technology to achieve complex and lightweight components.

Power equipment: The use of additive manufacturing technology in the design and manufacturing of nuclear power, hydropower, wind power, thermal power equipment, etc., to achieve rapid prototyping, direct manufacturing and repair of large and complex parts.

Rail transit equipment: Promote additive manufacturing technology to achieve rapid prototyping in new product development, process testing, and trial production of key components, to achieve multi-variety, small-volume, flexible manufacturing of key components, and to promote green and light rail transit equipment Quantitative development.

Home Appliances: Incorporating additive manufacturing technology into the design, research and development and process testing of home appliances, shortening the development cycle of new products, and promoting the integration of additive manufacturing technology into smart flexible manufacturing systems for home appliances to achieve personalized customization.

Mold: Using additive manufacturing technology to achieve mold optimization design, prototype manufacturing, etc.; promote the integrated molding of complex precision structure molds, shorten the development cycle; apply metal additive manufacturing technology to directly manufacture complex cavity molds.

Casting: Promote the application of additive manufacturing in key aspects such as model development, complex casting manufacturing, and casting repair, and develop casting special large-format sand-type (core) additive manufacturing equipment and related materials to promote the integration of additive manufacturing and traditional casting processes. .

Box 4 "3D Printing +" Demonstration Application

"3D printing + medical". For the needs of personalized medical devices (including medical non-medical devices), rehabilitation devices, implants, soft tissue repair, and new drug development in the medical field, we will promote the improvement of personalized medical additive manufacturing products in classification, clinical testing, registration, and market access. Other aspects of the policy and regulations, research and determine the medical service project fee standards and medical insurance support standards for medical additive manufacturing products and services.

"3D printing + cultural creativity." In response to the demand for innovative creative design, cultural and creative product development and personalized product consumption, the application of additive manufacturing technology in related fields will be promoted, new consumption hotspots will be cultivated, new consumption production models will be built, and consumption upgrade will be promoted.

"3D printing + innovative education." Implementing the school's additive manufacturing technology popularization project, encouraging the promotion of additive manufacturing technology in the field of education, deploying additive manufacturing equipment and teaching software, setting up additive manufacturing knowledge training courses, establishing additive manufacturing laboratories, and cultivating students' interest in innovative design , hobbies, consciousness. In primary and secondary schools, vocational colleges, etc., we will carry out science education for additive manufacturing, and carry out activities such as additive manufacturing design and skill competition.

"3D printing + internet". In response to the needs of the social public innovation and creativity, support additive manufacturing enterprises and Internet companies to cooperate, promote the establishment of a number of online collaborative design, data interconnection and distributed manufacturing additive manufacturing cloud platform, reduce application thresholds, promote the popularization of additive manufacturing technology . Promote the construction of innovative design, application and service centers for offline additive manufacturing, providing users with innovative design, product optimization, rapid prototyping, mold development and other application services.

Box 5 Sound Additive Manufacturing Standard System

New standard setting system. Develop national standards and industry standards for innovative design, special materials, process technology, equipment, inspection and testing, data and services, develop a number of group standards, and accelerate the construction of government-led standards and market-independent standards to coordinate and promote each other. The new standard manufacturing system for additive manufacturing.

Enterprise standard system. Encourage enterprises to speed up the formulation of a number of enterprise standards, establish a set of technical standards system for coordination, optimization and mutual coordination of relevant indicators, and promote enterprises to improve R&D and testing capabilities and management levels.

Standard Innovation Base. We will carry out pilot projects for the construction of technical standards and innovation bases in the field of additive manufacturing, and build a service platform that closely links standards, technology and industry to provide one-stop standardization services for enterprises and boost the standard capability of enterprises.

Standards for the conversion of results. Carry out the transformation of scientific and technological achievements in additive manufacturing into technical standards, build a database of scientific and technological achievements in additive manufacturing, establish rapid transformation of technological achievements in additive manufacturing into technical standard mechanisms, and promote a number of new technologies, new methods, new materials, and new materials for additive manufacturing. The process is quickly converted to standards.

Standard internationalization. In the fields of service and technology with certain advantages such as additive manufacturing cloud service platform and precision inspection, we actively take the lead in formulating international standards, enhance the right to speak internationally, and drive the “manufacturing” of additive manufacturing technologies and products.

Source of information: Ministry of Industry and Information Technology

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