application form - file · web viewrequest for information. issue date: february oo, 2017...

REQUEST FOR INFORMATION

ISSUE DATE: February OO, 2017

CLOSING DATE: March OO , 2017

SUBJECT: Request for Information (RFI) – Korea Evaluation Institute of Industrial technology (KEIT)

DESCRIPTION: Ministry of Trade, Industry and Energy (MOTIE) in Korea supports research and development (R&D) projects to promote innovative capability of Korean private industries and research institutions. The purpose of this RFI is to solicit prospective research ideas including the latest technology trend from industry, academia, research laboratories, and other stakeholders regarding future R&D directions of the MOTIE. Submitted RFIs will be reviewed by technical experts and KEIT Program Directors (PD) in the respective fields.

Based on the inputs of RFI and Korean government policies, KEIT will solicited new projects which will be announced to the public as a Funding Opportunity Announcement (FOA) around December 2017 (www.keit.re.kr). The total project budget typically ranges from 1.5 to 6 million dollars for three to five years as a part of “Industrial Strategic Technology Development Program”, which is one of the biggest MOTIE R&D program.

Foreign institutions including industry and academia can participate in a project as a sub-contractor or cooperative partner through a consortium with a lead Korean organization.

If an RFI submitted show greater prospect with participation with foreign partners, the project will be designated as the "Global Cooperation Track". For "Global Cooperation Track" project, foreign entity participation will be required to provide greater opportunity for international collaboration. However, the entities whose RFI contributes to the new FOA will not necessarily be the awardee. All awardees will be selected through a fair and open competition.

PROPRIETARY INFORMATION: Because information received in response to this RFI may be used to plan future programs and FOAs and/or otherwise could be made available to the public (only for review purpose), respondents should NOT include any information that might be considered business sensitive, proprietary, or otherwise confidential. Responses must be submitted with the understanding that their contents may be publicly disclosed and, in the event of a public disclosure, KEIT will NOT notify respondents or provide any opportunity to revise or redact submitted information.

RESPONSE GUIDELINES: All responses to this RFI must be provided as an attachment in an e-mail message addressed to [email protected] with the subject line “Response to RFI” no later than March OO, 2017. Responses must be provided as a Microsoft Word (.doc/.docx) file.

RESEARCH AREAS: KEIT is specifically interested to obtain inputs on following research areas listed in Core Investment Field Table (please see Attachment #1). Since a new project will be planned based on the research areas (i.e., Core Investment Field), please submit the technologies relevant to those areas. As KEIT is an R&D funding agency that promotes industrial technology, we would like to collect the ideas on the applied technology rather than the basic science.

Application Form

This form provides the Korea Evaluation Institute of Industrial technology (KEIT) with basic information about the applicant and the proposed project. Each applicant must complete this form. Applicants should select the project area, which best fits their project. If an applicant submits multiple applications (maximum up to 2 ), each application must be for a distinct project with different technology and objective.

1. Project Title

2. Applicant’s Identification Information

Name

Street Address

City, State, and Zip Code

Telephone

E-mail

Organization Name

Organization Type

Private Company Non-profit research institution Academic institution Government Entity (e.g., city, county, federal government) Others

3. Project Area (Place a check in the box applicable to the proposed project. Select up to two areas per application.)

Bio/medical technology Nanotechnology Knowledge service

engineering Automobile Semiconductor Plant engineering

(e.g., power plant, oil refinery, plant design, etc.)

Robotics

Smart electronics Ceramic Metallurgical technology Chemical process Display technology Shipbuilding and marine technology

Embedded software

Medical devices IT Fusion technology Textile & apparel Fundamental manufacturing

(e.g., molding, casting, plastic working, welding) Manufacturing system

(Precision machining, nanoscale manufacturing)

Machinery system(Construction/agriculture machine, analytical instruments)

4. Technical Description (2 page maximum)

I. Background, Rationale and Significance of proposed project

II. Prior Works

III. Objective & Proposed Technology

IV. Expected results and Benefits(Describe contribution to research and development for industry (e.g., performance enhancement of existing products, develop new products, etc.)

<Attachment #1> Core Investment Field Table

Strategy Core Topic Core Investment Fields (Draft)

Investing for 4th Industrial

Revolution Future Market

Expansion of the hyper-connected digital industry based on

Internet of Things (IoT)

1. Intelligent Internet of Things(IoT) components

2. Hyper-connected digital smart devices

3. Industrial platforms and hyper-connected services

Expansion of smart factories

4. Prediction & preservation technology for smart factories based on artificial intelligence

5. Virtualization to improve worker convenience/productivity technology

6. Energy management technology for supporting smart factory production optimization

7. Manufacturing artificial intelligence robots and equipment

Growth of the industry an intelligent unmanned

vehicle

8. Unmanned flying devices applicable to complex environments and operating system technology

9. Active control technology for self-driving and accident prevention/avoidance

10. Artificial intelligence based navigation, identification and judgment technology

11. Intelligent unmanned work system associated with ICT infra

Growth of the personalized healthcare

market

12. Diagnostic equipment and products to realize precision medical care

13. 3D printing based personalized products and services

14. Platforms and services based on health big data

Expansion in smart security and safety

demand

15. Smart security, safety platforms and services

16. Risk prevention and secure response management system construction

Growth of well-aging industry

17. Functional well-aging products and services

18. Rehabilitation, medical service robots

19. Universal design based life care servicesInvesting for core industry advancement

Eco-friendly transport machinery for responding

to environmental restrictions

20. Range improvement and price reduction for electric power vehicles

21. Eco-friendly vehicle charging infra and core components

Strategy Core Topic Core Investment Fields (Draft)22. Efficiency/performance improvement and

emission reduction of engine-based vehicles23. Eco-friendly smart ship technology24. Reducing environmental impact by employing

new high- efficiency and power system

New innovativecomposite material

25. Ultra-light, high-strength composite material and fabrication process

26. Composite material, components development for low-carbon, high-efficiency energy system

27. Functional Composite material for premium consumer goods

28. Bio material for better the quality of life29. High-tech materials for 3D printing

Securing high-tech manufacturing

equipment for setting up a continuous growth foundation of core

manufacturing industry

30. Additive production equipment(3D printing) for responding to future new manufacturing process

31. Ultra-precision processing equipment and process technology for responding to high-tech smart device production

32. Intelligent complex processing/manufacturing equipment for multi-product flexible automated production

Core Investment

Field1. Intelligent Internet of Things(IoT) components

Description(Overview and Scope)

ㅇ Develops intelligent Internet of Things(IoT) key components for expanding hyper-connected intelligent digital industry through communication with various things.

Core Investment

Field2. Hyper-connected digital smart devices

Description(Overview &

Scope)

ㅇ (Hyper-connected digital smart devices) refers to devices equipped with a data collection sensor from various working environments and with communication functions, providing information to users on a regular basis, such as connected vehicles, VR/AR and smarthome devices.

Core Investment

Field3. Industrial platforms and hyper-connected services


Scope)

ㅇ (Industrial platforms) refers to a platform that creates various services and high-value industries through data connection-intelligence-automation by accumulating various kinds of data calculated across industries such as transportation, manufacturing, consumer goods, telecommunication, petroleum and chemistry.

ㅇ (Hyper-connected services) Hyper-connected services refers to interactive intelligent networking environment and various services using this while all things equipped with digital-type platforms around are connected through networks, organically collecting and sharing information.

Core Investment

Field4. Prediction & preservation technology for smart

factories based on artificial intelligence


Scope)

ㅇ (Overview) Refers to technologies used to improve a productivity though an accurate prior prediction from a more objective perspective on error situations with the use of data collection and artificial intelligence techniques when it comes to a prediction on production situations dependent on existing specialized experiences and knowledge.

ㅇ (Scope) Unable to collect date on a situation that has not actually occurred and difficult to reproduce it artificially. Therefore, an artificial intelligence prediction technique that accurately predicts learning and an error situation automatically is developed by developing a reliably, virtually-created model that creates data on a situation that has not actually occurred and by using factory and facility operation data, virtually-created data using artificial intelligence techniques.

Core 5. Virtualization to improve worker

Investment Field convenience/productivity


Scope)

ㅇ (Overview) Refers to the technology that supports various kinds of information needed worker's manufacturing business in association with applications through UI based on virtualization.

ㅇ (Scope) Provides education/training using virtualization(VR/AR) devices/platforms, by providing information to support worker's tasks, building advanced design/simulation collaboration environments, with a possibility to extend into other services.

Core Investment

Field6. Energy management technology for supporting

smart factory production optimization


Scope)

ㅇ (Overview) Refers to the technology that allows surrounding smart factories to share energy consumption/surplus prediction information per workplace in real time for smart factories known as a consuming subject of intra-industry energy. This then promotes smart factories to be able to implement energy production, consumption, distribution and transactions based on workplace production optimization to create effective energy reduction effects in industrial fields.

ㅇ (Scope) Refers to standardized smart factory energy integration management service (FENS : Factory Energy Network Service) technology that involves not only energy reduction through energy resources management wasted in existing unit factories, but also predicting a long cycle/short cycle demand of the market based on big data related to materials, production, distribution and consumption, sharing energy information between smart factories by calculating predictable energy consumption and surplus needed accordingly to be able to support effective uses/management of surplus energy resources between smart factories through active energy management energy production/consumption/distribution/transaction based on production optimization associated with market consumption demand per smart factory.

Core Investment

7. Manufacturing artificial intelligence robots and equipment

Field


Scope)

ㅇ (Overview) Refers to advanced technological development of robots and equipment which designs/controls manufacturing robots that can do collaborative work with humans as well as study and make a decision, along with applicable IoT, CPS and cloud computing technologies to upgrade the entire manufacturing cycle according to digitalization and servitization of manufacturing industry and to build customized human-robot collaborative smart factories.

ㅇ (Scope) To build a smart factory, it is necessary to have manufacturing and design technologies for manufacturing artificial intelligence robots and equipment embedded with sensor technology, actuators, security technologies, optimization SW and recognition functions, particularly, there is a need to develop various robots and equipment for the application of a smart factory.

- Development of an artificial intelligence robot and equipment used in manufacturing process, e.g., part assembly.

. Part/obstacle recognition technology using Vision and a Laser Sensor

. Technological development for safety-enhanced drive modules and surrounding recognition technology for worker's intervention and collaboration work.

. Robot judgment intelligence field such as behavior plans through situational recognition

. Development of a robot arm terminal for assembly work . Creating a path for both-arm assembly work and development of

manipulation technology . Robot control technology allowing easy teaching and worker

intervention . Applying an IT product assembly process through developing

easy learning functions in artificial intelligence

Core Investment

Field8. Unmanned flying devices applicable to complex

environments and operating system technology


Scope)

ㅇ (Overview) Refers to operation system technologies that involve applicable

unmanned planes (drones) and the operation system that can

apply this to enable an effective response by conducting situations/damage investigations to rescue from all kinds of disaster likely to occur on the land and on the sea, such as fires, landslides, big fires and building collapse.

Develops unmanned plane operation system involving the acquiring of information on ocean ecology and fish biomass resources, such as floating matters in ocean environment, red tides, ocean temperature change and occurrence of oil pollution to make up for disadvantages in satellites and aviation images for resources management.

ㅇ (Scope) Refers to developing a water-proof UAV equipped with

communication and control systems for multiple unmanned planes (drones) transmitting real-time on-site information by immediately taking off upon the occurrence of disasters and flying according to disaster position information set, and designed to fly in spite of nasty weather conditions. This also is a UAV system operation system mounted with a near-infra red (NIR) sensor easy to search for disaster damage.

- Develops automated flight functions, Geo-fencing technology, and multiple unmanned plane operation technology

- Develops long-range operation technology using LTE communication system

- Develops operation system for making use of an unmanned plane in an area where ground communication system is collapsed by large-scale disaster

- Develops unmanned integration control/operation technology including control over multiple unmanned planes

- Illustration and analysis technology for disaster situations based on ground networks

Core Investment

Field9. Active control technology for self-driving and

accident prevention/avoidance


Scope)

ㅇ (Overview) Refers to active control technology enabling the prevention and avoidance of traffic accidents and autonomous driving by controlling a vehicle based on surrounding situation recognition. Traffic accident prevention/avoidance technology includes the stand-alone system using a vehicle-mounted sensor, the cooperative safety method based on system-vehicle (V2V) communication and vehicle-infra (V2I) communication and the method combined with the above two. Autonomous driving system comes as a pattern of autonomous-driving system with judgment and control technologies.

ㅇ (Scope) Active control technology for self-driving vehicles - Refers to the technology that prevents traffic accidents or

minimizes human/property damage in the event of a traffic accident by providing driver warning or by conducting longitudinal(acceleration/deceleration) and transverse(steering) control based on the information acquired through the vehicle-mounted sensor and V2V/V2I communication.

- The stand-alone accident prevention/avoidance system includes curved area warning system, front vehicle collision warning/control system, lane keeping control system, lane departure warning system, pedestrian/bicycle collision warning/control system and parting assist system.

- V2X based integrated safety system includes various product groups, such as V2V based front vehicle collision alert system, V2V based urgent control warning system, V2I/V2V based incident automatic notification system, overtaking danger warning system, and V2I based intersection collision alert system.

- The autonomous driving system now comes in the emerging market with 4 items, such as TJA (Traffic Jam Assist), HDA(Highway Driving Assist), autonomous parking and vehicle lane change, being developed into valet parking associated further with infra.

- With autonomous driving system active control technology being developed into level 3, 4 or over, it includes various next-generation technological developments such as driving priority and point determination through mutual negotiations among autonomous driving vehicles, as well as hand signals associated with artificial intelligence, recognition of an atypical object and response, cut, crossing and merge

- The control of an autonomous vehicle consists of the route creation and follow-up including the road to the destination, vehicle lane selection and right and left turns, the path creation and follow-up involved in driving after calculating a free space using the avoidance of surrounding vehicles and obstacles according to short-range traffic situations, the acceleration/deceleration and automatic steering control enabling a vehicle to drive this way, as well as several mode control units in consideration and safety.

Core Investment

Field10. Artificial intelligence based navigation,

identification and judgment technology


Scope)

ㅇ (Overview) Refers to target navigation technology in environment and conditions using a surveillance sensor (Electronic optics, radar, 3D rider) based on technologies for unmanned moving object self-driving, autonomous navigation and autonomous flight, target identification technology through signal merging and processing and technologies combined with image processing and Neuro-fuzzy based artificial intelligence type judgment technology.

ㅇ (Scope) Situation recognition/control by an intelligent unmanned object and the judgment system for an non-cooperative target.

- A target detection and situation recognition technology based on a multiple sensor in consideration of operating environment and dynamic characteristics.

- Result merging and target detection technology through high-speed parallel signal processing of big data per sensor.

- Target recognition (NCTR: Non-cooperative Target Recognition) technology for a target and a moving object using artificial intelligence Neuro Fuzzy algorithm and hierarchical database.

- Long-distance communication and task control technology for data exchange with the base station and for conducting instructions and commands.

Core Investment

Field11. Intelligent unmanned work system associated with

ICT infra


Scope)

ㅇ (Overview) Refers to work (production) machine system providing intellectualized tasks or services through semi-autonomous or autonomous operations ((Mobility & Manipulation) by recognizing and judging surrounding environment on its own in an unspecific outdoor environment.

ㅇ (Scope) Includes intelligent construction machinery/farming machinery, three-dimensional farming production system, smart construction system, precision farming system, remove management system (Telematics), and unmanned intellectualized assist parts and S/W.

Core Investment

Field12. Diagnostic equipment and products to realize

precision medical care

Description ㅇ Precision medicine using personalized medical science is a field

(Overview & Scope)

of medical science with an objective of providing accurate treatment to each person by integrating research performances and clinical treatment.

- It is applied by finding out appropriate medicines and treatment methods for patients by joining fundamental medicine researchers and clinical investigators such as genetics in the existing doctor-patient relationship.

- Refers to a comprehensive concept that precisely diagnoses and treats the entire phase of genetic, environmental and biological characteristics ranging from diagnosis to treatment to suit requirements of individual patients by introducing molecular profiling technology in clinical pathology.

Core Investment

Field13. 3D printing based personalized products and

services


Scope)

ㅇ Refers to a field that provides customized products and services in manufacturing-based medical devices and service industries, taking such 3D medical infused printing enabling innovative process introduction and wearable devices (including sensors) dealing with all data regarding activities in everyday life and systems and convenience services using this.

- Everyday life data refers to personalized life-log data acquired through personal exercise, diet, sleep and biometry signals, enabling personalized services to be provided using this.

- The application of 3D printing enables the consumer-focused process innovation in direct user participation and diversified services through this, instead of manufacturing simply customized devices or products.

Core Investment

Field14. Platforms and services based on health big data


Scope)

ㅇ Refers to personalized health management service system and services that can analyze, utilize and provide big data platforms based on personal health information and stored data.

- Enables creating a new application value by putting humans, medical devices and data together while making extraction and sharing possible by building platforms based on clinical and health data.

Core Investment

Field15. Smart security, safety platforms and services


Scope)

ㅇ Develops platforms and services that can make a connection between safety, security products and services equipped with multi-functions and high performance through the convergence with IT and various technologies.

Core Investment

Field16. Risk prevention and secure response management

system construction


Scope)

ㅇ Promotes systematic development of safety industry through the technology-based construction merged with ICT designed to prevent danger in industrial facilities (e.g., manufacturing facilities, industrial complex and power plants) and to secure safety.

* Technology market accounts for 63.5% in the world's disaster safety market, among which ICT field application market accounts for 81.5%. (‘14, Homeland Security Research Corp)

- (Virtual training system) Refers to convergence system that implements virtual environment similar to industrial fields, reduces safety-related danger by operating and training a virtual object merged with on-site experience knowledge and improves a productivity through a reduction in training period and cost reduction.

- (Quantitative risk assessment) Promotes systematic development of safety-related industry through presenting the criteria for risk management capable of predicting risk types, sizes and occurrence frequency effectively.

Core Investment

Field17. Functional well-aging products and services


Scope)

ㅇ (Overview) Well-aging products and services include business areas for products and services for beauty care and for healing body and mental health for active silver, meaning the continual sustenance of healthy life, that is, products and services that improve the convenience and satisfaction in everyday life.

ㅇ (Scope) Refers to management and function improvement products and services related to beauty care and mind and mental health among age-friendly products and services, including industries related to functional cosmetics, functional clothes, health functional food and skin care and regeneration, except for personalized medical supplies and medical devices and wellness resort industries.

Core Investment

Field18. Rehabilitation, medical service robots


Scope)

ㅇ (Overview) Refers to products and product-based services (Health promotion, rehabilitation devices, pain relief devices and intelligent mobile devices) to promote mental, physical health, convenience and safety for complementing physical, mental

functions and for the elderly showing biological aging and socioeconomic ability deterioration in consideration of the elderly's physical and mental characteristics.

ㅇ (Scope) Refers to products and product-based services such as health promotion and rehabilitation devices for the elderly, pain relief devices, intelligent mobile devices, along with challenging, future-oriented and human-friendly products and services based on human engineering and human reinforcement such as Bionic-Limb.

Core Investment

Field19. Universal design based life care services


Scope)

ㅇ (Overview) Refers to products and services that help enable the elderly to make an independent living by supporting and improving convenience and stability of the elderly's everyday life.

erydaysilver : Indicates senior citizens showing active consumption attitudes for ※themselves, valuing health with active spirits and holding substantial buying power.

ㅇ (Scope) Refers to wellness devices and services rather than medical equipment for active silver capable of more independent living to some degree than inpatient seniors.

Core Investment

Field20. Range improvement and price reduction for

electric power vehicles


Scope)

ㅇ (Overview) With strengthening environmental regulation, demand for Eco-friendly vehicles grow and the importance of technical advancement and economic competitiveness will be crucial for sustainable market penetration.

ㅇ (Scope) - Performance improvements in energy storage and range

improvement is needed for wide distribution. - Fuel cell electric vehicles have secured the world's best

technological power but are necessary to enhance price competitiveness for vehicle distribution and popularization.

- Hybrid vehicles are also slightly more expensive than engine-based vehicles with a need of energy storage device retaining price competitiveness.

Core Investment

Field21. Eco-friendly vehicle charging infra and core

components


Scope)

ㅇ (Overview) It is required to build and expand low cost/high efficiency infra for an Eco-friendly commercialization and market growth.

ㅇ (Scope) Eco-friendly vehicles such as an electric vehicle and a

fuel cell vehicle are operated through charging hydrogen, with such essential factors as charging system and core components for constructing charging infra such as production of electricity or hydrogen, supply, storage, conversion and safe control.

* Refers to effective operation and management technologies of charging infra associated with charging technologies, such as rapid charging technology for cutting an electric vehicle charging time, battery exchange method and wireless charging technology and smart grid, telematics and ITS.

* To distribute hydrogen electric vehicles, it is essential to secure infra but the localization ratio of a hydrogen charging station built domestically stays at 40%, representing the continuous development of component localization and safety management capable of preventing safety-related accidents.

Core Investment

Field22. Efficiency/performance improvement and emission

reduction of engine-based vehicles


Scope)

ㅇ (Overview) Refers to vehicles mounted with a high-efficiency engine that can respond to next exhaust gas restrictions and global warming gas restrictions of advanced countries such as Europe by improving the fuel efficiency significantly compared to the existing internal-combustion engine and by reducing toxic exhaust gas

ㅇ (Scope) Refers to technologies for optimizing the engine structure for responding to fuel efficiency and emission restrictions of an engine-based vehicle, and for improving new combustion technology and intake and exhaust system efficiency.

- Refers to control technologies that include low-emission combustion technologies for meeting diesel vehicle emission restrictions, system and operation optimization, post-exhaust processing performance improvement and related sensors.

- Refers to development of Eco-friendly power system and core components of export-led industrial machinery, such as construction machines, farming machines and industrial vehicles (Forklift).

- It is essential to improve actual exhaust performance improvement under the current circumstances as to the satisfaction to fuel efficiency of an internal-combustion vehicle, the main part of auto industry, and CO2 emission restrictions (95g/km in 2020 over 130g/km in 2015 based on EU standards) as well as it holds most of market share.

* An internal-combustion engine is expected to take up a portion not only as a source of power in the actual main model but also as a main source of power in generation with (P)HEV system.

Core Investment

Field23. Eco-friendly smart ship technology

Description ㅇ (Overview) Refers to Eco-friendly smart ships and technologies

(Overview & Scope)

designed to deal with strengthening international regulations on ocean environments, a growing demand for economic navigation and an intelligent ship based on ICT fusion technologies.

ㅇ (Scope) Includes Eco-friendly smart ships for actively protecting ocean environment and for optimal navigation, LNG fuel-driven ship with an ocean plant technology, development of the optimal shape of ship, fuel reduction technology, environment-friendly material development, optimal navigation path system, integrated control system, intelligent maintenance and safety diagnosis and autonomous navigation system.

Core Investment

Field24. Reducing environmental impact by employing new

high-efficiency and power system


Scope)

ㅇ (Overview) Refers to developing efficient Eco-friendly industrial machinery (construction and farm machines) based on low carbon power system in accordance with environmental regulations (emission, noise and vibrations).

ㅇ (Scope) Includes electricity and hybrid power technology, system design technology including engine miniaturization and power source, high efficiency system reflecting working environment and operating mode and energy recovery system.

Core Investment

Field25. Ultra-light, high-strength composite material and

fabrication process


Scope)

ㅇ Refers to transport machinery, ultra-light high-intensity composite new material for extreme environment and safety/protection as well as process and equipment capable of the production and process with an effective use of this.

- (Material for transport machinery) Refers to ultra-light

highly durable material designed to respond to international environmental regulations by substantially reducing energy and carbon dioxide (CO2) consumed in transport through weight lightening of transport machinery, such as aircraft, vehicles and ships.

- (Material for extreme environment) Refers to special materials, which are ultra-light, ultra strong, highly touch, highly heat resistant, and highly insulated, and that can fully exercise functions in extreme environments, such as space, hottest place, ocean plant, mega structure, renewable energy (wind power, tidal power, wave power).

- (Safety/protective material) Includes ultra-light, ultra strong, highly elastic, highly heat resistant, and highly flame resistant and chemically resistant safety/protective material that is used in products for disasters, disaster protection, military purposes and work wear/protection.

Core Investment

Field26. Composite material, components development for

low-carbon, high-efficiency energy system


Scope)

ㅇ Refers to composite materials, components and processes for conversion to low-carbon, high-efficiency energy system to respond to depletion and diversification of energy resources, climate change and deepening environmental issues.

- (Power high efficiency materials, components) Refers to lightweight, miniaturized, low-loss and high temperature and high pressure materials and components for power high efficiency and safety purposes, such as power plant and high efficiency of power transmission and distribution and nuclear safety materials.

- (Energy storage materials and components) Include energy storage materials and components featuring high capacity, high output, high intensity and high flexibility, with applications in electric vehicle (EV), fuel cell vehicle(FCV), energy storage system(ESS) and wearable smart devices.

- (Energy material, component application and verification) Refers to verifying by applying developed next generation materials and components in energy supply(generation), transport, delivery and demand (usage) sectors and to securing a track record.

Core Investment

Field27. Functional Composite material for premium

consumer goods


Scope)

ㅇ Includes multi-functional high-performance composite materials and products using this to improve the convenience of life by implementing smart living and to improve consumer's satisfaction by meeting highly sensitive needs.

- (Smart material) Refers to electronic functional convergence materials and products* fused with ICT and smart materials and products** to implement optimal living convenience such as self-function display-type materials

* Includes newly designed parts and products so materials and electronic devices equipped with electronic functions should be integrated for a smart living.

** Refers to materials that demonstrate functions themselves without external help, such as self-healing, self-cleaning, self-discoloration, self-diagnosis and self-luminosity.

- (Highly functional material) Refers to a limit performance restoration type material* that can implement various (new) functions but also provides high properties, including materials and products essential in the growth of future industry becoming high tech including nano materials.

* Includes high tech materials that can implement various functions needed for products at a high level, featuring heat resistance, cold resistance, weather resistance, soil resistance, chemical resistance, insulation resistance, wear resistance, high mobility, high conductivity, electromagnetic shielding, anti-pollution and light resistance, scratch resistance, high heat radiation and high dielectrics.

- (High-sensitivity material and consumer products) Refers to consumer-oriented highly sensitive materials and consumer products capable of meeting consumer's satisfaction by providing various functionalities and improving aesthetics.

Core Investment

Field28. Bio material for better the quality of life


Scope)

ㅇ Refers to biomedical materials for diagnosis and treatment to enhance the quality of human life in preparation for aging society as well as Eco-friendly materials harmless to humans.

- (Bio medical material) Includes medical materials such as biocompatible materials for artificial organs, alternative bone substitute and joints, drug delivery material, bio-therapies materials and bio sensor materials for smart diagnosis

- (Bio-friendly materials) Includes harmless materials from natural substances derived from natural objects, biodegradation materials and bio chemicals.

Core Investment

Field29. High-tech materials for 3D printing


Scope)

ㅇ (3D printing based manufacturing process innovation) It is expected that the manufacturing process innovation where the manufacturing industry mega-sized by the centralized, large-scale capital type through 3D printing is decentralized will occur. To expand 3D printing, it is crucial to achieve manufacturing and process development for material selection and performance improvement.

ㅇ (Highly functional 3D printing material) Refers to 3D high-tech material that will provide a competitiveness in early commercialization and industrialization.

- Refers to application technology between different types of materials according to 3D printing metal, high molecules, an application field of ceramic material and property of needs.

- Includes high-tech material technology such as functionally gradient materials in layered manufacturing, elastic body and textile products.

Core Investment

Field30. Additive production equipment(3D printing) for

responding to future new manufacturing process


Scope)

ㅇ (Overview) Refers to technology that causes a paradigm with a product manufacturing process simplifying the conventional complicated manufacturing process, which includes new manufacturing equipment that manufactures materials such as 3-dimensional digital model with the layer-by-layer method.

ㅇ (Scope) Main element technologies comprising layered manufacturing equipment are defined as modeling (design and SW), equipment(process, core component, system technology) and post-processing process technology according to layered process stages.

Core Investment

Field

31. Ultra-precision processing equipment and process technology for responding to high-tech smart device production


Scope)

ㅇ (Overview) Refers to next-generation optical parts in charge of information input/output such as wearable type devices, smartphones and augmented type devices, as well as ultra-precision equipment responsible for processing semiconductors, displays and micro-miniature electronic devices, parts and process technology development.

ㅇ (Scope) Includes processing process for ultra-precision shape parts and system, ultra-fine laser processing system, fine pattern roll forming system, large area fine shape forming system, ultra-fine particle beam processing system, and high precision grinding system technology.

Core Investment

Field

32. Intelligent complex processing/manufacturing equipment for multi-product flexible automated production


Scope)

ㅇ (Overview) Refers to high-performance, high-efficiency and multiple collaboration equipment and process technology applying intellectualization and convergence to support improvements in the efficiency and productivity in the process of small quantity batch production.

ㅇ (Scope) Includes complex processing machine, highly flexible multitasking processing machine, Turn-Mill machine, B-axis machine, high speed processing system, multi-axis/multi-functional processing system, difficult-to-cut material processing system, and robot collaboration processing system.

application form - file · web viewrequest for information. issue date: february oo, 2017...

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