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시장보고서
상품코드
2025432
성형 섬유 포장 시장(2026-2036년)The Global Moulded Fibre Packaging Market 2026-2036 |
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일회용 플라스틱에 대한 규제, 상업적, 소비자 측면의 압력이 증가함에 따라 세계 성형 섬유 포장 시장은 향후 10년간 지속적인 확장기에 접어들 것으로 보입니다. EU의 포장 및 포장 폐기물 규정(PPWR)은 유럽 전역에서 포장 디자인의 변화를 가져오고 있으며, 생산자책임재활용제도(EPR)는 아시아, 라틴아메리카, 북미에서 빠르게 확산되고 있습니다. 또한, PFAS 규제로 인해 내유-내유성 코팅의 전면적인 재설계가 요구되고 있습니다. 이러한 요인들로 인해 브랜드 소유자와 가공업체들은 점점 더 많은 응용 분야에서 섬유 유래 대체품으로 전환해야 하는 상황에 직면해 있습니다.
소매 식품 및 음료는 여전히 가장 큰 최종 용도 부문으로, 계란 팩, 과일 및 채소 트레이, 와인병 보호재, 그리고 새롭게 주목받고 있는 종이 및 섬유 기반 식수 병이 그 핵심입니다. 푸드서비스(테이크아웃 용기, 뚜껑, 컵 홀더, 소모품 중심)는 가장 빠르게 성장하고 있는 주류 부문입니다. 브랜드 소유주들이 플라스틱을 사용하지 않는 1차 및 2차 포장에 대한 노력을 기울이면서, 의료 및 화장품 용도가 확대되고 있습니다. 한편, 가전제품 및 가전제품 제조업체들은 운송 및 보호용 포장에 발포 폴리스티렌(EPS) 대신 성형 섬유를 사용하는 경향이 증가하고 있으며, 이 분야는 이커머스의 지속적인 성장으로 인해 새로운 동력을 얻고 있습니다.
기술 혁신으로 인해 성형 섬유의 가능성은 재정의되고 있습니다. PulPac과 그 라이선스를 받은 기업이 선도적으로 개발한 건식 성형 섬유는 물 사용과 에너지 소비를 줄이면서 기존 종이, 판지, 열성형 설비에서 생산할 수 있습니다. BfR XXXVI에 따른 습식 내유성 및 내유성 화학물질, 마이크로피브릴화 셀룰로오스(MFC) 기반의 100% 셀룰로오스 배리어, PFAS가 없는 바이오폴리머 분산액으로 섬유의 한계로 여겨지던 식품접촉 용도에 대한 길을 열어줍니다. 산업용 대마 및 기타 차세대 셀룰로오스 원료는 병, 튜브 및 컨테이너의 중공 성형 생산에 시험적으로 적용되고 있으며, AI를 활용한 외관 검사 및 공정 열공학을 통해 습식 및 건식 성형 공급망 전체에서 수율을 개선하고 단위 원가를 낮추고 있습니다.
과제는 여전히 남아있습니다. 성형 섬유는 일반적으로 동급 플라스틱 포장에 비해 비용이 더 높습니다. 또한, 광범위한 경제적 불확실성으로 인해 투자 결정이 지연되고 있으며, 장벽 성능을 파일럿 규모에서 산업 규모로 확대하기 위해서는 섬유, 화학, 금형, 충진 각 파트너 간의 긴밀한 협력이 필요합니다. 지역별 성장 역학도 불균등합니다. 아시아태평양과 아프리카는 낮은 수준에서 빠르게 추격하고 있지만, 서유럽과 북미는 여전히 규제적으로 세계 방향성을 결정짓는 견인차 역할을 하고 있습니다. 2036년까지 종이화, 순환경제, 화석연료 플라스틱 대체가 섬유 포장의 전체 가치사슬에서 경쟁 전략을 결정지을 것으로 예측됩니다.
이 보고서는 세계 성형 섬유 포장 시장을 조사했으며, 7개 최종 용도 부문과 7개 지역에 걸쳐 수요를 재편하고 있는 규제, 거시경제 및 기술 요인을 추적하고 성형 섬유 가치사슬 전반에 걸쳐 활동하는 150개 이상의 기업을 분석합니다.
목차
제1장 주요 요약
제2장 서론과 조사 방법
제3장 거시경제 상황
제4장 규제 상황과 시장 성장 촉진요인
제5장 기술 분석
제6장 경쟁 구도로 사례 연구
제7장 최종 용도 시장과 예측
제8장 지역 시장과 예측
제9장 기업 개요(107사 개요)
제10장 조사 범위와 조사 방법
제11장 참고 문헌
LSHThe global moulded fibre packaging market is entering a decade of sustained expansion, driven by converging regulatory, commercial and consumer pressures on single-use plastics. The EU Packaging and Packaging Waste Regulation (PPWR) is reshaping packaging design across Europe, Extended Producer Responsibility (EPR) schemes are proliferating across Asia, Latin America and North America, and PFAS restrictions are forcing wholesale reformulation of grease- and oil-resistant coatings. Together, these forces are pushing brand owners and converters toward fibre-based alternatives across an expanding range of applications.
Retail food and drink remains the largest end-use segment, anchored by egg cartons, produce trays, wine-bottle protection and the nascent but high-profile category of paper and fibre-based beverage bottles. Foodservice - led by takeaway containers, lids, cup carriers and disposables - is the fastest-growing mainstream segment. Medical and cosmetics applications are expanding as brand owners commit to plastic-free primary and secondary packaging, while consumer electronics and appliance makers increasingly substitute moulded fibre for expanded polystyrene (EPS) in transit and protective packaging - an area given fresh impetus by the continued growth of e-commerce.
Technology innovation is reshaping what moulded fibre can do. Dry-moulded fibre, pioneered by PulPac and its licensees, reduces water use and energy intensity while enabling production on existing paper, board and thermoforming equipment. Wet-end oil-and-grease-resistant chemistries compliant with BfR XXXVI, 100% cellulose barriers based on microfibrillated cellulose (MFC), and PFAS-free bio-polymer dispersions are opening food-contact applications previously closed to fibre. Industrial hemp and other next-generation cellulosic feedstocks are being trialled in hollow-shape production of bottles, tubes and containers, while AI-driven visual inspection and process-heat engineering are lifting yield and lowering unit cost across the wet- and dry-moulded supply base.
Challenges remain. Moulded fibre typically carries a cost premium over comparable plastic packaging, investment decisions are slowed by broader economic uncertainty, and converting barrier performance from pilot to industrial scale demands close collaboration across fibre, chemistry, tooling and filling partners. Regional growth dynamics are also uneven: Asia-Pacific and Africa are catching up rapidly from a lower base, while Western Europe and North America continue to provide the regulatory pull that sets the global direction of travel. Paperisation, circularity and the substitution of fossil-based plastics are set to define competitive strategy across the fibre packaging value chain through 2036.
The Global Moulded Fibre Packaging Market 2026–2036 delivers a comprehensive, data-rich analysis of one of the fastest-growing segments of sustainable packaging. Built on primary research and extensive secondary analysis, the report maps the market across seven end-use segments and seven regions, tracks the regulatory, macroeconomic and technological forces reshaping demand, and profiles more than 150 companies active across the moulded fibre value chain - from fibre producers and moulding machinery suppliers to barrier-coating chemistry specialists, brand owners and technology consortia.
The report provides detailed 10-year forecasts to 2036, with granular breakdowns for retail food and drink, foodservice, FMCG and cosmetics, industrial and engineered packaging, single-use medical, horticulture and consumer durables. Technology coverage spans wet-moulded, dry-moulded and thermoformed fibre, hollow-shape production of bottles and tubes, BfR XXXVI-compliant wet-end OGR chemistries, 100% cellulose MFC barriers, PFAS-free bio-polymer dispersions, process-heat engineering and AI-driven visual inspection. Regulatory analysis covers PPWR, SUPD, EPR, PFAS restrictions and global food-contact frameworks.
Report contents include:
- Executive summary and key market indicators
- Introduction, scope and methodology
- Macroeconomic landscape (GDP, inflation, energy, e-commerce)
- Regulatory landscape and market drivers
- Technology analysis: feedstocks, processes, barriers, paper bottles
- Competitive landscape and case studies
- End-use markets and forecasts to 2036
- Regional markets and forecasts to 2036
- Company profiles
- Research methodology and references
Companies profiled include Acorn Pulp Group, Advanced Paper Forming, Ahlstrom, AIM Sweden, Amcor, Apeel Sciences, Aquapak Polymers, Archroma, Arkema, Artemyn, BASF, Be Green Packaging, Bcomp, Billerud, BIO-LUTIONS, Blue Ocean Closures, Borregaard, Brødrene Hartmann, Buhl Paperform, Capsul'in Pro, Cellucomp, CelluForce, Cellutech (Stora Enso), Celwise, Cirkla, CKF, Clariant, CreaFill Fibers, Cruz Foam, Cullen Eco-Friendly Packaging, Dalton Electric Heating, Danish Technological Institute, DIC Corporation, Domtar Paper, Dow, Earthodic, E6PR, Ecologic Brands, Eco-Products, Eco-SQ, EcoSynthetix, Ecovative Design, E-molding International, EMPPA, EnviroPAK, EURIKAS, Fibercel Packaging, Fiberdom, FiberLean Technologies, Fibmold, Follmann, Footprint, Fraunhofer Institutes, Frugalpac, Futamura Chemical, Genera, Genpak, Golden Arrow, Grenoble INP – Cellulose Valley, H.B. Fuller, Henry Molded Products, Heracles Packaging, Holmen Iggesund, Huhtamaki, HZ Green Pulp, Infinited Fiber Company, International Paper, J&J Green Paper, JOS Consulting, Kagzi Bottles, Keiding, Kelpi, Kemira, Kiefel, Koehler Paper, Kotkamills (Metsa Board), KRONES, Kuraray, Lactips, Lean Orb, Lvran Tech, Mantrose-Haeuser, Matrix Pack, MCC Verstraete, Melodea, Metsa Board Corporation, Metsa Spring, Michelman, Michelsen Packaging, Mondi, Moulded Pulp Engineering, The Navigator Company, Nfinite Nanotech, Nippon Paper Industries, Nippon Molding, Nippn Corp, Notpla, Oji Holdings, Omni-Pac Group, Omya
TABLE OF CONTENTS
1 EXECUTIVE SUMMARY
- 1.1 Plastics packaging issues
- 1.2 Moulded fibre market
- 1.2.1 Increased demand in recent years will continue
- 1.2.2 Meeting sustainability needs
- 1.2.3 New coatings technologies
- 1.2.4 In-house tooling
- 1.2.5 Paperisation and plastic substitution
- 1.2.6 Cost gap between moulded fibre and plastic alternatives
- 1.3 Advantages of moulded fibre packaging
- 1.4 Packaging megatrends
- 1.5 Main market players
- 1.6 Global revenues for moulded fibre packaging, 2026–2036 (millions USD)
- 1.7 Market segmentation for moulded fibre packaging, 2026–2036 (millions USD)
- 1.8 Regional segmentation for moulded fibre packaging, 2026–2036 (revenues, millions USD)
- 1.9 Market and technology challenges
- 1.10 Key questions answered within this report
2 INTRODUCTION AND METHODOLOGY
- 2.1 Report scope and objectives
- 2.2 Methodology
- 2.3 Market definitions and segmentation conventions
- 2.4 Currency, exchange rates and constant-dollar treatment
3 MACROECONOMIC LANDSCAPE
- 3.1 Key highlights
- 3.2 Real GDP growth by key regions, 2020–2036
- 3.3 US 12-month percentage change, consumer price index
- 3.4 Asia-Pacific: annual percentage change, end-of-period consumer prices
- 3.5 Natural gas prices for EU household consumers, 2015–2025
- 3.6 Natural gas prices for EU non-household consumers, 2015–2025
- 3.7 Economic uncertainty and impact on capital investment decisions
- 3.8 Global retail e-commerce sales outlook to 2036
4 REGULATORY LANDSCAPE AND MARKET DRIVERS
- 4.1 EU Packaging and Packaging Waste Regulation (PPWR)
- 4.2 EU Single-Use Plastics Directive (SUPD)
- 4.3 Extended Producer Responsibility (EPR) schemes worldwide
- 4.4 BfR XXXVI compliance for direct food contact
- 4.5 PFAS restrictions and the shift to fluorine-free chemistries
- 4.6 Corporate sustainability disclosure obligations
- 4.7 Cost sensitivity and the price gap with plastic
- 4.8 Urbanisation and consumer concerns
- 4.9 Recyclability and compostability requirements
5 TECHNOLOGY ANALYSIS
- 5.1 Cellulose fibre sources
- 5.1.1 Virgin fibres
- 5.1.1.1 Bagasse
- 5.1.1.2 Shredded bamboo
- 5.1.1.3 Wheat straw
- 5.1.1.4 Industrial hemp
- 5.1.1.5 Next-generation cellulosic feedstocks
- 5.1.2 Recycled fibres
- 5.1.2.1 Fibre recycling processes
- 5.1.2.2 Contaminants and food-contact risk for recycled pulp
- 5.1.1 Virgin fibres
- 5.2 Manufacturing processes
- 5.2.1 Mechanical pulping and chemical pulping
- 5.2.2 Forming process
- 5.2.3 Drying process
- 5.2.4 3D printing
- 5.2.5 Process heat as a design variable
- 5.2.6 AI-driven visual inspection and in-line quality control
- 5.3 Types of moulded pulp
- 5.3.1 Wet moulding
- 5.3.1.1 Thick-wall (Type 1)
- 5.3.1.2 Transfer moulded (Type 2)
- 5.3.1.3 Thermoformed fibre (Type 3)
- 5.3.1.4 Processed pulp (Type 4)
- 5.3.2 Dry-moulded / thermoformed fibre
- 5.3.2.1 Dry-moulded fibre on existing paper/board/thermoforming lines
- 5.3.2.2 Fibre functionalisation — plastic-free natural fibre materials
- 5.3.3 Hollow shapes — scaling bottles, containers and tubes
- 5.3.3.1 Closing the gap between prototype and industrial-scale production
- 5.3.3.2 Automated production systems and cycle-time stability
- 5.3.1 Wet moulding
- 5.4 Properties of moulded products
- 5.4.1 Grades and prices
- 5.4.2 Additives
- 5.4.3 Strength and lightweighting
- 5.4.4 Formability, humidity resistance and end-of-life trade-offs
- 5.5 Barrier coatings and functional layers
- 5.5.1 Bio-based wet-end oil and grease resistant (OGR) solutions
- 5.5.2 BfR XXXVI-compliant wet-end chemistries
- 5.5.3 100% cellulose barriers — microfibrillated cellulose (MFC) and double-dipping
- 5.5.4 PFAS-free bio-polymer dispersions and bio-based wax emulsions
- 5.5.5 Nanocellulose and plasma coatings
- 5.5.6 Multi-layer barrier architectures and lamination
- 5.6 Paper and fibre-based bottles
- 5.6.1 Wet-moulded fibre bottles
- 5.6.2 Dry-moulded paper bottles — state of development
- 5.6.3 Paper-based caps and closures
- 5.6.4 Downstream: cleaning, filling and secondary packaging
- 5.7 E-commerce and transit packaging: moulded fibre vs EPS
6 COMPETITIVE LANDSCAPE AND CASE STUDIES
- 6.1 Key highlights
- 6.2 Industry associations and consortia
- 6.3 Case study: PulPac and Diageo — Johnnie Walker paper bottle
- 6.4 Case study: Tony's Chocolonely moulded fibre advent calendar (SFA Packaging)
- 6.5 Case study: Metsa Spring — moulded fibre food trays with barrier film
- 6.6 Case study: Stora Enso and Matrix Pack innovation partnership
- 6.7 Case study: Flora
- 6.8 Case study: Yangi — pilot-to-production collaboration model
- 6.9 Case study: Fiberdom Duranova® — plastic-free fibre on existing lines
- 6.10 Case study: Grenoble INP / Cellulose Valley LCA — wet, dry and plastic thermoformed trays
7 END-USE MARKETS AND FORECASTS
- 7.1 Foodservice
- 7.1.1 Products (takeaway, disposables)
- 7.1.2 Global market 2026–2036 (revenues and tonnes)
- 7.2 Retail food and drink
- 7.2.1 Products
- 7.2.2 Global market 2026–2036 (revenues and tonnes)
- 7.3 Fast-moving consumer goods (FMCG) including cosmetics
- 7.3.1 Products
- 7.3.2 Global market 2026–2036 (revenues and tonnes)
- 7.4 Industrial and engineered packaging
- 7.4.1 Electronics packaging
- 7.4.2 Vehicle / automotive parts packaging
- 7.4.3 E-commerce transit and protective packaging (moulded fibre vs EPS)
- 7.4.4 Global market 2026–2036 (revenues and tonnes)
- 7.5 Single-use medical
- 7.5.1 Products
- 7.5.2 Global market 2026–2036 (revenues and tonnes)
- 7.6 Horticultural
- 7.6.1 Products
- 7.6.2 Global market 2026–2036 (revenues and tonnes)
- 7.7 Consumer durables
- 7.7.1 Consumer electronics
- 7.7.2 Electrical appliances
- 7.7.3 Other durables
- 7.7.4 Global market 2026–2036 (revenues and tonnes)
- 7.8 End-use market CAGR comparison
8 REGIONAL MARKETS AND FORECASTS
- 8.1 North America
- 8.1.1 United States
- 8.1.2 Canada
- 8.1.3 Mexico
- 8.2 South & Central America
- 8.2.1 Brazil
- 8.2.2 Other South and Central America
- 8.3 Western Europe
- 8.3.1 France
- 8.3.2 Germany
- 8.3.3 Italy
- 8.3.4 Spain
- 8.3.5 United Kingdom
- 8.3.6 Other Western Europe
- 8.4 Eastern Europe
- 8.4.1 Poland
- 8.4.2 Russia
- 8.4.3 Other Eastern Europe
- 8.5 Middle East and Africa
- 8.5.1 Turkey
- 8.5.2 Other Middle East
- 8.5.3 Africa
- 8.6 Asia-Pacific
- 8.6.1 China
- 8.6.2 India
- 8.6.3 Japan
- 8.6.4 Other Asia-Pacific
- 8.7 Australasia
- 8.8 Country-level CAGR comparison
9 COMPANY PROFILES (107 company profiles)
10 RESEARCH SCOPE AND METHODOLOGY
- 10.1 Report scope
- 10.2 Research methodology
