Post Show Report
주요 수치
만족도 조사 결과 : 83% 만족 표시
1,500명 이상
업체 465 개사
참여국가 43개
3 일
연사 30명
혁신상 수상업체 4개사
스타트업 부스터 수상업체 2개사
11개 세션
참여 현황
활동 분야 - %
- 복합소재 엔드유저
- 복합소재 부품 제조 및 시험장비 생산업체
- 복합소재 부품 생산업체
- 원료 생산업체
- 협회, 제 3자, 서비스 및 컨설턴트
- 유통업체, 에이전트, 대리인
- 화이버/레진 기반 반제품 중간재 생산업체
- 원료 및 중간재 제조 장비 생산업체
- 화이버 기반 섬유 중간재 생산업체
- 설계/제조용 소프트웨어 공급업체
- 제조장비와 함께 사용되는 소모품 생산업체
- 기타 반제품 중간재 생산업체
- 복합소재, 중간재 및 완제품 재활용 업체
참여국가 상위 10개국
1. 한국
2. 호주
3. 인도
4. 독일
5. 일본
기술 컨퍼런스
기술 컨퍼런스 3개 세션
라이브 참여 285명
연사 21명
3일 동안 최고 수준의 기술 컨퍼런스 개최. 컨퍼런스 라인업 :
CG Rail GmbH, COMI S.p.A, Engel Austria GmbH, Engel Machinery Korea Ltd, Fagor Arrasate, INEOS Styrolution Group GmbH, Mitsui Chemicals, Ouchi Ocean Consultant Ltd, Schmidt & Heinzmann, Simutence GmbH, Toray Advanced Composites
스타트업 부스터
아시아 지역 첫 번째 스타트업 부스터는 JEC Asia 2019에서 시작
JEC Asia 2019 부터 시작된 스타트업 부스터 대회는 한국무역협회와 공동 주관
2019년에는 결승에 진출한 10개사 중 5개사가 한국 업체였으며 이로써 한국의 경제적 역동성을 다시 한번 보여주었습니다. 2020년에는 수상업체 2개사 중 한국 업체 1개사가 선정되었습니다.
2020년 수상 업체
LIGNUM (South Korea)
Innovative and advanced bio-based plastic revolutionizing future mobility
스타트업 부스터는 혁신적인 복합소재 분야의 최고 전문가들로 구성된 심사위원들과 함께 합니다.
- Jelle BLOEMHOF, Head of Manufacturing Technologies of Composite, Airbus
- Arne BOETTCHER, Market Development & Venture Manager Composites, Covestro
- Karl-Heinz FUELLER, Manager Future Outside & Materials, Daimler
- 박선경 혁신생태계실장, 무역협회
- 신현규 탄소비즈니스센터장, 한국탄소융합기술원
스타트업 프로그램 높은 만족도 : 86%
JEC 혁신상
JEC 혁신상 수상업체
EV 배터리 케이스용 유리 복합소재
Light-weight battery cases can be produced with this new fast curing galss epoxy prepreg flame retardant and ready for mass production.
Hankuk Carbon has developed an Epoxy Glass Prepreg, with fast curing resin (4 mins / 150℃) dedicated to mass production. Therefore, it is possible to apply prepreg compression molding (PCM) technology that uses the press method. Moreover it turns out that this material is suitable for all the components using sheet molding methods. Particularly, the material is suitable for producing EV battery case that requires flame retardancy with the UL-94 V0 Grade. Specifically, it can be applied to battery cover as well as to the lower part tray of battery where high mechanical properties are required. In addition, it features similar mechanical properties as carbon fabric and low-cost material compared to carbon fabric.
프로젝트 파트너 Deutsches Luft- und Raumfahrtzentrum (DLR) (Germany), Gubesch Group(Germany), Christian Karl Siebenwurst GmbH & Co. KG (Germany), SCHMIDT Gesellschaft für Werkzeug- und Formentechnik mbH (Germany)and Raschig GmbH (Germany).
터번 스트럿의 열경화성 인몰드 성형
The innovation is the integrative production of a turbine strut based on a combination of prepreg compression molding and thermoset injection molding in one mold.
The Institute of Polymer Technology together with its partners has developed an innovative process (called Duro-IMF) for the production of rework-free, hybrid components made of thermoset fibre composites, which have the highest lightweight construction potential. These components enable a considerable weight reduction, e.g. by substituting metallic components, and thus reduce fuel consumption and emissions in flight operations. Furthermore, the material and energy efficiency of the process is higher than that of conventional processes. In the integrative process, an uncrosslinked thermoset semi-finished product is formed by the closing movement of the mold and then functionalized by injection molding with an uncrosslinked short-fiber-reinforced thermoset molding compound. Both components then cure together. The joint curing reduces the cycle time compared to conventional comparable processes. In addition, crosslinking reactions and diffusion processes occur at the interface as a result of the joint spatial and simultaneous crosslinking. This leads to a significant increase in bond strength, which allows the application in aviation technologies. Also, 2D and 3D functional elements can be directly integrated by injection molding and only one mold is required. The implementation of the innovative integrative process was realized by an aerodynamic fairing of a turbine strut for an aircraft turbine of the thrust class 70 kN.
프로젝트 파트너 Dongsung Corporation (Republic of Korea), Korea Institute of Carbon Convergence Technology (KCTECH) (Republic of Korea), Korea Textile Machinery Convergence Research Institute (KOTMI) (Republic of Korea) and LG Hausys (Republic of Korea).
고성능 탄소섬유 SMC 기계
High performance carbon fiber SMC machine enabling higher mechanical properties, cost reduction, VOC-free SMC and ease of maintenance.
Compared to conventional SMC machine, which is generally for glass fiber, developed SMC machine is optimized for carbon fiber. To realize carbon fiber SMC, some parts has been added and enhanced; carbon fiber cutting, spreading & dividing, multiple resin layers, metered and temperature controllable resin supply and carbon fiber transfer unit. 1. Carbon fiber optimized cutting : carbon fiber chopper, consisting of rotating blade roll and groove roll, has innovative cutting mechanism. Appropriate tension is applied by drawing carbon fibers. Cutting blades, located in rotating cutting roll, continuously penetrate dug of the groove roll to cut carbon fiber. This promotes reliable high-speed cutting and longer life of blades. 2. One-line carbon fiber spreading & dividing : considering the cost and impregnation of carbon fiber, this process is highly required in carbon fiber SMC. Carbon fiber is spread by going through heating bars and oscillating spreading bars. Slitting knives divide large K CF(50K) into small K CF(3K). This enables cost reduction and uniform physical properties. 3. Multiple resin layers New SMC machine improves impregnation by adding extra resin layers in between chopped carbon fiber layers by vertical slot dies. More than three (at least, bottom, middle and top) resin layers induces better wet-out, super-high CF contents (up to 65%) and high-speed production possible than conventional SMC machine. 4. Metered and temperature controllable resin supply : using metering pump enables ease manipulation of resin supply. Due to resin temperature control, high viscous resins such as VOC-free resins are usable in developed SMC system. 5. Enhanced carbon fiber transfer : to avoid carbon fiber damage, tendency driver rollers were applied to new machine. Steel pull roll was used to alternate conventional rubber nip roll. As a result, damage to carbon fiber was diminished by lowering friction and it enables SMC present high mechanical properties.
47% 레진으로 구성된 컨셉 자동차
This design concept can only be achieved by making the entire body out of resin. The CFRP suspension system works for repeated deformation by giving the properties both toughness and stiffness.
The surface configuration of continuous curved surfaces, the large glass area and opening doors, the independent front fender, and the covered rear wheels are all components of this vehicle, which has both a futuristic style and superior aerodynamic performance that contributes to energy saving. The monocoque frame serves as the outer body with the excellent physical properties by thermosetting composites due to light weight, high stiffness and collision safety. The weight, was achieved a reduction of more than 50% from the 300kg of the conventional metal frame to 140kg. The CFRP parts worked for suspension system in the car even though it has been conventionally difficult to be made of resin. It also been realized not only for the main suspension components, but also for the spring with large deformations. The front is a CFRP leaf spring suspension combined with arm of a double wishbone. This contributed to the establishment of a distinctive independent fender and anticipated the layout with vibration-damping which is one of the features of the composite structure. The coil spring at rear side works for repeating deformation by giving both toughness and stiffness.
높은 만족도 : 86%