Japan Engineering Plastics Market SIZE & SHARE ANALYSIS - GROWTH TRENDS & FORECASTS UP TO 2029

The Japan Engineering Plastics Market is segmented by End User Industry (Aerospace, Automotive, Building and Construction, Electrical and Electronics, Industrial and Machinery, Packaging) and by Resin Type (Fluoropolymer, Liquid Crystal Polymer (LCP), Polyamide (PA), Polybutylene Terephthalate (PBT), Polycarbonate (PC), Polyether Ether Ketone (PEEK), Polyethylene Terephthalate (PET), Polyimide (PI), Polymethyl Methacrylate (PMMA), Polyoxymethylene (POM), Styrene Copolymers (ABS and SAN)). Market Value in USD and Volume in tons are both presented. Key Data Points observed include volume of automobile production, new construction floor area, plastic packaging production volume, plastic resin production, imports and exports, and price of plastic resins.

Japan Engineering Plastics Market Size

Japan Engineering Plastics Market Summary

Japan Engineering Plastics Market Analysis

The Japan Engineering Plastics Market size is estimated at 5.72 billion USD in 2024, and is expected to reach 7.59 billion USD by 2029, growing at a CAGR of 5.80% during the forecast period (2024-2029).

Japan's engineering plastics industry continues to evolve amid significant technological and industrial transformations. The electronics sector, a major consumer of engineering plastics, demonstrated remarkable resilience with a 2% year-over-year increase in domestic production in 2022, reaching USD 84.34 billion. This growth has been primarily driven by the strong performance of electronic components and devices in exports, alongside increasing demand for electric measuring instruments due to 5G technology adoption. The integration of electronic components in vehicles has further accelerated the demand for high-performance engineering plastics, particularly in applications requiring enhanced thermal and chemical resistance.


The automotive sector remains a cornerstone of Japan's engineering plastics consumption, with vehicle production reaching 9.41 million units in 2022, marking a 3.49% increase from the previous year. The industry's shift toward electric vehicles and lightweight components has spurred innovation in technical plastics applications, particularly in under-the-hood components and structural elements. Japanese automakers are increasingly incorporating advanced performance plastics to reduce vehicle weight and improve fuel efficiency, while maintaining structural integrity and performance standards.


The aerospace and defense sectors are emerging as significant growth drivers for industrial plastics in Japan. The government's commitment to strengthening defense capabilities is evident in the 26.3% increase in defense spending, with a budget of JPY 6.82 trillion approved for fiscal year 2023. This substantial investment, coupled with plans to raise defense spending to 2% of GDP by 2027, is creating new opportunities for advanced polymers in military and aerospace applications, particularly in components requiring high performance under extreme conditions.


Sustainability initiatives and regulatory frameworks are reshaping the engineering plastics landscape in Japan. The country's commitment to environmental stewardship has led to an increased focus on recyclable plastics and bio-based engineering plastics. Major manufacturers are investing in research and development of sustainable alternatives, while maintaining the high-performance characteristics required by end-user industries. The government's implementation of the Plastic Resource Circulation Strategy, aiming to reuse or recycle all plastic waste by 2035, is driving innovation in recyclable engineering plastic formulations and manufacturing processes.

Segment Analysis: End User Industry

Electrical and Electronics Segment in Japan Engineering Plastics Market

The electrical and electronics segment dominates the Japan engineering plastics market, commanding approximately 31% market share in 2024. This segment's prominence is driven by the widespread applications of engineering plastics like ABS/SAN, PC, and PA in advanced and smart electrical devices. The segment's leadership position is reinforced by Japan's excellence in producing components and devices, particularly in key technologies such as all-solid batteries and medical cameras. The government's efforts toward decarbonization and the industry's proficiency in this field continue to enable further innovations, especially in factory automation and telework-led workstyle reforms. Additionally, this segment is experiencing the fastest growth trajectory, with an expected growth rate of around 8% during 2024-2029, primarily due to the rapid adoption of lightweight and high-impact resistant engineering plastics to replace traditional metal parts in electronic applications.

Market Analysis of Japan Engineering Plastics Market: Chart for End User Industry

Remaining Segments in End User Industry

The Japan engineering plastics market encompasses several other significant end-user segments, including automotive, industrial machinery, packaging, building and construction, and aerospace sectors. The automotive segment represents the second-largest market share, with automotive plastics being extensively used in vehicle components, particularly for lightweighting applications. The industrial machinery sector maintains substantial demand for industrial plastics in manufacturing various components like bushes, gears, and bearings. The packaging industry utilizes engineering plastics primarily in rigid packaging applications, while the building and construction sector employs these materials in various structural and decorative applications. The aerospace segment, though smaller in market share, demonstrates significant potential due to the increasing adoption of aerospace plastics and lightweight materials in aircraft manufacturing. Each of these segments contributes uniquely to the market's dynamics, driven by specific industry requirements and technological advancements.

Segment Analysis: Resin Type

PET Segment in Japan Engineering Plastics Market

Polyethylene terephthalate (PET) maintains its position as the dominant segment in Japan's engineering plastics market, commanding approximately 30% of the market share in 2024. This substantial market presence is primarily driven by PET's extensive applications in the packaging industry, particularly in bottle and container manufacturing. The material's clear, strong, lightweight, and 100% recyclable properties make it the preferred choice for food and beverage packaging applications. The segment's growth is further supported by Japan's robust packaging industry and increasing consumer demand for sustainable packaging solutions. Major manufacturers like MCT PET Resin Co. Ltd and Mitsubishi Chemical Corporation are actively expanding their production capacities to meet the rising demand, while also focusing on developing recycled PET (rPET) solutions to align with Japan's sustainability goals.

LCP Segment in Japan Engineering Plastics Market

Liquid Crystal Polymer (LCP) has emerged as the fastest-growing segment in Japan's engineering plastics market, projected to experience robust growth during 2024-2029. The segment's exceptional growth is primarily driven by increasing demand from the electrical and electronics industry, particularly in 5G network communication systems and high-performance electronic components. Japanese manufacturers like Sumitomo Chemicals and Daicel Corporation are expanding their LCP production capacities to meet the growing demand from various end-use industries. The material's unique properties, including excellent thermal stability, chemical resistance, and dimensional stability, make it particularly suitable for miniaturized electronic components and high-frequency applications. The segment's growth is further supported by increasing adoption in aerospace applications and the automotive sector's shift towards lightweight materials.

Remaining Segments in Resin Type

The Japanese engineering plastics market encompasses several other significant segments, including polycarbonate (PC), polyamide (PA), Styrene Copolymers (ABS and SAN), PMMA, POM, and PEEK plastic. Each of these segments serves specific industrial applications with unique material properties. Polycarbonate dominates in optical and electronic applications due to its transparency and impact resistance. Polyamide finds extensive use in automotive and industrial applications owing to its mechanical strength and thermal stability. Styrene copolymers are crucial in consumer electronics and automotive applications, while specialized resins like ABS plastic and POM cater to high-performance industrial applications. These segments collectively contribute to the market's diversity and cater to Japan's sophisticated manufacturing sector, particularly in automotive, electronics, and industrial machinery applications.

Japan Engineering Plastics Industry Overview

Top Companies in Japan Engineering Plastics Market

The Japanese engineering plastics market is characterized by continuous product innovation, with leading manufacturers focusing on developing high-performance materials for various industries. Companies are investing heavily in research and development to create sustainable solutions, including bio-based polymers and recycled content materials. Operational agility has become crucial as manufacturers adapt to changing market demands, particularly in the automotive and electronics sectors. Strategic moves in the industry primarily revolve around capacity expansions, with several players announcing new production lines and facility upgrades to meet growing demand. Companies are also forming strategic partnerships and joint ventures to strengthen their market position and expand their product portfolios, particularly in specialized segments like liquid crystal polymers and high-performance polyamides.

Highly Consolidated Market Led By Conglomerates

The Japanese engineering plastics market exhibits a highly consolidated structure dominated by large domestic conglomerates with integrated operations. These major players, including Mitsubishi Chemical Corporation, Techno-UMG, and Daicel Corporation, have established strong vertical integration from raw material procurement to end-product manufacturing. The market is characterized by high entry barriers due to the significant capital requirements and technical expertise needed for manufacturing engineering plastics. The presence of well-established distribution networks and long-standing relationships with key end-users further strengthens the position of incumbent players.


The market has witnessed significant merger and acquisition activity, with companies pursuing strategic consolidation to enhance their market presence and technological capabilities. Notable transactions include Daicel Corporation's acquisition of Polyplastics and the formation of joint ventures between Japanese and international players to combine technological expertise and market access. These consolidation trends have resulted in the emergence of stronger market players with enhanced capabilities in specialized product segments and improved operational efficiency.

Innovation and Sustainability Drive Future Success

For incumbent players to maintain and expand their market share, focusing on technological innovation and sustainable solutions will be crucial. Companies need to invest in developing new grades of specialty plastics and high-temperature plastics that meet evolving industry requirements, particularly in emerging applications like electric vehicles and 5G technology. Building stronger relationships with key end-users through collaborative development projects and customized solutions will be essential. Additionally, establishing efficient recycling infrastructure and developing products with recycled content will become increasingly important as sustainability regulations tighten.


New entrants and smaller players can gain ground by focusing on specialized market segments and developing innovative solutions for specific applications. Success will depend on building strong technical capabilities and establishing partnerships with established players for market access. Companies must also consider the high concentration of end-users in the automotive and electronics sectors, which necessitates maintaining high-quality standards and reliable supply chains. While substitution risk from alternative materials exists, engineering plastics' unique properties and established position in key applications provide some protection. Future regulatory changes, particularly regarding environmental sustainability and recycling requirements, will likely shape market dynamics and create opportunities for companies with advanced technological capabilities.

Japan Engineering Plastics Market Leaders

  1. Daicel Corporation

  2. MCT PET Resin Co Ltd

  3. Mitsubishi Chemical Corporation

  4. Sumitomo Chemical Co., Ltd.

  5. Techno-UMG Co., Ltd.

  6. *Disclaimer: Major Players sorted in no particular order
Japan Engineering Plastics Market Concentration
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Japan Engineering Plastics Market News

  • October 2022: AGC Inc. introduced Fluon+ Composites functionalized fluoropolymers that improve the performance of carbon fiber-reinforced thermoplastic (CFRP and CFRTP) composites used in automobiles, aircraft, sports products, and printed circuit boards.
  • August 2022: Toray Industries Inc. introduced Toraypearl PA6, which claims to provide outstanding high strength, heat resistance, and surface smoothness for powder bed fusion 3D printers.
  • August 2022: Mitsui Chemicals and Teijin Limited formed a joint venture to produce and supply biomass polycarbonate resins across Japan.

Free With This Report

We provide a complimentary and exhaustive set of data points on global and regional metrics that present the fundamental structure of the industry. Presented in the form of 15+ free charts, the section covers rare data on various end-user production trends including passenger vehicle production, commercial vehicle production, motorcycle production, aerospace components production, electrical and electronics production, and regional data for engineering plastics demand etc.

Japan Engineering Plastics Market
Japan Engineering Plastics Market
Japan Engineering Plastics Market
Japan Engineering Plastics Market

Japan Engineering Plastics Market Report - Table of Contents

1. EXECUTIVE SUMMARY & KEY FINDINGS

2. REPORT OFFERS

3. INTRODUCTION

  • 3.1 Study Assumptions & Market Definition
  • 3.2 Scope of the Study​
  • 3.3 Research Methodology

4. KEY INDUSTRY TRENDS

  • 4.1 End User Trends
    • 4.1.1 Aerospace
    • 4.1.2 Automotive
    • 4.1.3 Building and Construction
    • 4.1.4 Electrical and Electronics
    • 4.1.5 Packaging
  • 4.2 Import And Export Trends
  • 4.3 Price Trends
  • 4.4 Recycling Overview
    • 4.4.1 Polyamide (PA) Recycling Trends
    • 4.4.2 Polycarbonate (PC) Recycling Trends
    • 4.4.3 Polyethylene Terephthalate (PET) Recycling Trends
    • 4.4.4 Styrene Copolymers (ABS and SAN) Recycling Trends
  • 4.5 Regulatory Framework
    • 4.5.1 Japan
  • 4.6 Value Chain & Distribution Channel Analysis

5. MARKET SEGMENTATION (includes market size in Value in USD and Volume, Forecasts up to 2029 and analysis of growth prospects)

  • 5.1 End User Industry
    • 5.1.1 Aerospace
    • 5.1.2 Automotive
    • 5.1.3 Building and Construction
    • 5.1.4 Electrical and Electronics
    • 5.1.5 Industrial and Machinery
    • 5.1.6 Packaging
    • 5.1.7 Other End-user Industries
  • 5.2 Resin Type
    • 5.2.1 Fluoropolymer
    • 5.2.1.1 By Sub Resin Type
    • 5.2.1.1.1 Ethylenetetrafluoroethylene (ETFE)
    • 5.2.1.1.2 Fluorinated Ethylene-propylene (FEP)
    • 5.2.1.1.3 Polytetrafluoroethylene (PTFE)
    • 5.2.1.1.4 Polyvinylfluoride (PVF)
    • 5.2.1.1.5 Polyvinylidene Fluoride (PVDF)
    • 5.2.1.1.6 Other Sub Resin Types
    • 5.2.2 Liquid Crystal Polymer (LCP)
    • 5.2.3 Polyamide (PA)
    • 5.2.3.1 By Sub Resin Type
    • 5.2.3.1.1 Aramid
    • 5.2.3.1.2 Polyamide (PA) 6
    • 5.2.3.1.3 Polyamide (PA) 66
    • 5.2.3.1.4 Polyphthalamide
    • 5.2.4 Polybutylene Terephthalate (PBT)
    • 5.2.5 Polycarbonate (PC)
    • 5.2.6 Polyether Ether Ketone (PEEK)
    • 5.2.7 Polyethylene Terephthalate (PET)
    • 5.2.8 Polyimide (PI)
    • 5.2.9 Polymethyl Methacrylate (PMMA)
    • 5.2.10 Polyoxymethylene (POM)
    • 5.2.11 Styrene Copolymers (ABS and SAN)

6. COMPETITIVE LANDSCAPE

  • 6.1 Key Strategic Moves
  • 6.2 Market Share Analysis
  • 6.3 Company Landscape
  • 6.4 Company Profiles (includes Global Level Overview, Market Level Overview, Core Business Segments, Financials, Headcount, Key Information, Market Rank, Market Share, Products and Services, and Analysis of Recent Developments).
    • 6.4.1 AGC Inc.
    • 6.4.2 Asahi Kasei Corporation
    • 6.4.3 Daicel Corporation
    • 6.4.4 Daikin Industries, Ltd.
    • 6.4.5 Kuraray Co., Ltd.
    • 6.4.6 Kureha Corporation
    • 6.4.7 MCT PET Resin Co Ltd
    • 6.4.8 Mitsubishi Chemical Corporation
    • 6.4.9 PBI Advanced Materials Co.,Ltd.
    • 6.4.10 Polyplastics-Evonik Corporation
    • 6.4.11 Sumitomo Chemical Co., Ltd.
    • 6.4.12 Techno-UMG Co., Ltd.
    • 6.4.13 Teijin Limited
    • 6.4.14 Toray Industries, Inc.
    • 6.4.15 UBE Corporation

7. KEY STRATEGIC QUESTIONS FOR ENGINEERING PLASTICS CEOS

8. APPENDIX

  • 8.1 Global Overview
    • 8.1.1 Overview
    • 8.1.2 Porter’s Five Forces Framework (Industry Attractiveness Analysis)
    • 8.1.3 Global Value Chain Analysis
    • 8.1.4 Market Dynamics (DROs)
  • 8.2 Sources & References
  • 8.3 List of Tables & Figures
  • 8.4 Primary Insights
  • 8.5 Data Pack
  • 8.6 Glossary of Terms
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List of Tables & Figures

  1. Figure 1:  
  2. PRODUCTION REVENUE OF AEROSPACE COMPONENTS, USD, JAPAN, 2017 - 2029
  1. Figure 2:  
  2. PRODUCTION VOLUME OF AUTOMOBILES, UNITS, JAPAN, 2017 - 2029
  1. Figure 3:  
  2. FLOOR AREA OF NEW CONSTRUCTION, SQUARE FEET, JAPAN, 2017 - 2029
  1. Figure 4:  
  2. PRODUCTION REVENUE OF ELECTRICAL AND ELECTRONICS, USD, JAPAN, 2017 - 2029
  1. Figure 5:  
  2. PRODUCTION VOLUME OF PLASTIC PACKAGING, TONS, JAPAN, 2017 - 2029
  1. Figure 6:  
  2. IMPORT REVENUE OF ENGINEERING PLASTICS BY RESIN TYPE, USD, JAPAN, 2017 - 2021
  1. Figure 7:  
  2. EXPORT REVENUE OF ENGINEERING PLASTICS BY RESIN TYPE, USD, JAPAN, 2017 - 2021
  1. Figure 8:  
  2. PRICE OF ENGINEERING PLASTICS BY RESIN TYPE, USD PER KG, JAPAN, 2017 - 2021
  1. Figure 9:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 10:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 11:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED BY END USER INDUSTRY, TONS, JAPAN, 2017 - 2029
  1. Figure 12:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED BY END USER INDUSTRY, USD, JAPAN, 2017 - 2029
  1. Figure 13:  
  2. VOLUME SHARE OF ENGINEERING PLASTICS CONSUMED BY END USER INDUSTRY, %, JAPAN, 2017, 2023, AND 2029
  1. Figure 14:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED BY END USER INDUSTRY, %, JAPAN, 2017, 2023, AND 2029
  1. Figure 15:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED IN AEROSPACE INDUSTRY, TONS, JAPAN, 2017 - 2029
  1. Figure 16:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED IN AEROSPACE INDUSTRY, USD, JAPAN, 2017 - 2029
  1. Figure 17:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED IN AEROSPACE INDUSTRY BY RESIN TYPE, %, JAPAN, 2022 VS 2029
  1. Figure 18:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED IN AUTOMOTIVE INDUSTRY, TONS, JAPAN, 2017 - 2029
  1. Figure 19:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED IN AUTOMOTIVE INDUSTRY, USD, JAPAN, 2017 - 2029
  1. Figure 20:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED IN AUTOMOTIVE INDUSTRY BY RESIN TYPE, %, JAPAN, 2022 VS 2029
  1. Figure 21:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED IN BUILDING AND CONSTRUCTION INDUSTRY, TONS, JAPAN, 2017 - 2029
  1. Figure 22:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED IN BUILDING AND CONSTRUCTION INDUSTRY, USD, JAPAN, 2017 - 2029
  1. Figure 23:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED IN BUILDING AND CONSTRUCTION INDUSTRY BY RESIN TYPE, %, JAPAN, 2022 VS 2029
  1. Figure 24:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED IN ELECTRICAL AND ELECTRONICS INDUSTRY, TONS, JAPAN, 2017 - 2029
  1. Figure 25:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED IN ELECTRICAL AND ELECTRONICS INDUSTRY, USD, JAPAN, 2017 - 2029
  1. Figure 26:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED IN ELECTRICAL AND ELECTRONICS INDUSTRY BY RESIN TYPE, %, JAPAN, 2022 VS 2029
  1. Figure 27:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED IN INDUSTRIAL AND MACHINERY INDUSTRY, TONS, JAPAN, 2017 - 2029
  1. Figure 28:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED IN INDUSTRIAL AND MACHINERY INDUSTRY, USD, JAPAN, 2017 - 2029
  1. Figure 29:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED IN INDUSTRIAL AND MACHINERY INDUSTRY BY RESIN TYPE, %, JAPAN, 2022 VS 2029
  1. Figure 30:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED IN PACKAGING INDUSTRY, TONS, JAPAN, 2017 - 2029
  1. Figure 31:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED IN PACKAGING INDUSTRY, USD, JAPAN, 2017 - 2029
  1. Figure 32:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED IN PACKAGING INDUSTRY BY RESIN TYPE, %, JAPAN, 2022 VS 2029
  1. Figure 33:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED IN OTHER END-USER INDUSTRIES INDUSTRY, TONS, JAPAN, 2017 - 2029
  1. Figure 34:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED IN OTHER END-USER INDUSTRIES INDUSTRY, USD, JAPAN, 2017 - 2029
  1. Figure 35:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED IN OTHER END-USER INDUSTRIES INDUSTRY BY RESIN TYPE, %, JAPAN, 2022 VS 2029
  1. Figure 36:  
  2. VOLUME OF ENGINEERING PLASTICS CONSUMED BY RESIN TYPE, TONS, JAPAN, 2017 - 2029
  1. Figure 37:  
  2. VALUE OF ENGINEERING PLASTICS CONSUMED BY RESIN TYPE, USD, JAPAN, 2017 - 2029
  1. Figure 38:  
  2. VOLUME SHARE OF ENGINEERING PLASTICS CONSUMED BY RESIN TYPE, %, JAPAN, 2017, 2023, AND 2029
  1. Figure 39:  
  2. VALUE SHARE OF ENGINEERING PLASTICS CONSUMED BY RESIN TYPE, %, JAPAN, 2017, 2023, AND 2029
  1. Figure 40:  
  2. VOLUME OF FLUOROPOLYMER CONSUMED BY SUB RESIN TYPE, TONS, JAPAN, 2017 - 2029
  1. Figure 41:  
  2. VALUE OF FLUOROPOLYMER CONSUMED BY SUB RESIN TYPE, USD, JAPAN, 2017 - 2029
  1. Figure 42:  
  2. VOLUME SHARE OF FLUOROPOLYMER CONSUMED BY SUB RESIN TYPE, %, JAPAN, 2017, 2023, AND 2029
  1. Figure 43:  
  2. VALUE SHARE OF FLUOROPOLYMER CONSUMED BY SUB RESIN TYPE, %, JAPAN, 2017, 2023, AND 2029
  1. Figure 44:  
  2. VOLUME OF ETHYLENETETRAFLUOROETHYLENE (ETFE) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 45:  
  2. VALUE OF ETHYLENETETRAFLUOROETHYLENE (ETFE) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 46:  
  2. VALUE SHARE OF ETHYLENETETRAFLUOROETHYLENE (ETFE) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 47:  
  2. VOLUME OF FLUORINATED ETHYLENE-PROPYLENE (FEP) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 48:  
  2. VALUE OF FLUORINATED ETHYLENE-PROPYLENE (FEP) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 49:  
  2. VALUE SHARE OF FLUORINATED ETHYLENE-PROPYLENE (FEP) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 50:  
  2. VOLUME OF POLYTETRAFLUOROETHYLENE (PTFE) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 51:  
  2. VALUE OF POLYTETRAFLUOROETHYLENE (PTFE) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 52:  
  2. VALUE SHARE OF POLYTETRAFLUOROETHYLENE (PTFE) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 53:  
  2. VOLUME OF POLYVINYLFLUORIDE (PVF) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 54:  
  2. VALUE OF POLYVINYLFLUORIDE (PVF) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 55:  
  2. VALUE SHARE OF POLYVINYLFLUORIDE (PVF) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 56:  
  2. VOLUME OF POLYVINYLIDENE FLUORIDE (PVDF) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 57:  
  2. VALUE OF POLYVINYLIDENE FLUORIDE (PVDF) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 58:  
  2. VALUE SHARE OF POLYVINYLIDENE FLUORIDE (PVDF) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 59:  
  2. VOLUME OF OTHER SUB RESIN TYPES CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 60:  
  2. VALUE OF OTHER SUB RESIN TYPES CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 61:  
  2. VALUE SHARE OF OTHER SUB RESIN TYPES CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 62:  
  2. VOLUME OF LIQUID CRYSTAL POLYMER (LCP) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 63:  
  2. VALUE OF LIQUID CRYSTAL POLYMER (LCP) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 64:  
  2. VALUE SHARE OF LIQUID CRYSTAL POLYMER (LCP) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 65:  
  2. VOLUME OF POLYAMIDE (PA) CONSUMED BY SUB RESIN TYPE, TONS, JAPAN, 2017 - 2029
  1. Figure 66:  
  2. VALUE OF POLYAMIDE (PA) CONSUMED BY SUB RESIN TYPE, USD, JAPAN, 2017 - 2029
  1. Figure 67:  
  2. VOLUME SHARE OF POLYAMIDE (PA) CONSUMED BY SUB RESIN TYPE, %, JAPAN, 2017, 2023, AND 2029
  1. Figure 68:  
  2. VALUE SHARE OF POLYAMIDE (PA) CONSUMED BY SUB RESIN TYPE, %, JAPAN, 2017, 2023, AND 2029
  1. Figure 69:  
  2. VOLUME OF ARAMID CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 70:  
  2. VALUE OF ARAMID CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 71:  
  2. VALUE SHARE OF ARAMID CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 72:  
  2. VOLUME OF POLYAMIDE (PA) 6 CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 73:  
  2. VALUE OF POLYAMIDE (PA) 6 CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 74:  
  2. VALUE SHARE OF POLYAMIDE (PA) 6 CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 75:  
  2. VOLUME OF POLYAMIDE (PA) 66 CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 76:  
  2. VALUE OF POLYAMIDE (PA) 66 CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 77:  
  2. VALUE SHARE OF POLYAMIDE (PA) 66 CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 78:  
  2. VOLUME OF POLYPHTHALAMIDE CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 79:  
  2. VALUE OF POLYPHTHALAMIDE CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 80:  
  2. VALUE SHARE OF POLYPHTHALAMIDE CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 81:  
  2. VOLUME OF POLYBUTYLENE TEREPHTHALATE (PBT) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 82:  
  2. VALUE OF POLYBUTYLENE TEREPHTHALATE (PBT) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 83:  
  2. VALUE SHARE OF POLYBUTYLENE TEREPHTHALATE (PBT) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 84:  
  2. VOLUME OF POLYCARBONATE (PC) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 85:  
  2. VALUE OF POLYCARBONATE (PC) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 86:  
  2. VALUE SHARE OF POLYCARBONATE (PC) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 87:  
  2. VOLUME OF POLYETHER ETHER KETONE (PEEK) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 88:  
  2. VALUE OF POLYETHER ETHER KETONE (PEEK) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 89:  
  2. VALUE SHARE OF POLYETHER ETHER KETONE (PEEK) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 90:  
  2. VOLUME OF POLYETHYLENE TEREPHTHALATE (PET) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 91:  
  2. VALUE OF POLYETHYLENE TEREPHTHALATE (PET) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 92:  
  2. VALUE SHARE OF POLYETHYLENE TEREPHTHALATE (PET) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 93:  
  2. VOLUME OF POLYIMIDE (PI) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 94:  
  2. VALUE OF POLYIMIDE (PI) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 95:  
  2. VALUE SHARE OF POLYIMIDE (PI) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 96:  
  2. VOLUME OF POLYMETHYL METHACRYLATE (PMMA) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 97:  
  2. VALUE OF POLYMETHYL METHACRYLATE (PMMA) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 98:  
  2. VALUE SHARE OF POLYMETHYL METHACRYLATE (PMMA) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 99:  
  2. VOLUME OF POLYOXYMETHYLENE (POM) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 100:  
  2. VALUE OF POLYOXYMETHYLENE (POM) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 101:  
  2. VALUE SHARE OF POLYOXYMETHYLENE (POM) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 102:  
  2. VOLUME OF STYRENE COPOLYMERS (ABS AND SAN) CONSUMED, TONS, JAPAN, 2017 - 2029
  1. Figure 103:  
  2. VALUE OF STYRENE COPOLYMERS (ABS AND SAN) CONSUMED, USD, JAPAN, 2017 - 2029
  1. Figure 104:  
  2. VALUE SHARE OF STYRENE COPOLYMERS (ABS AND SAN) CONSUMED BY END USER INDUSTRY, %, JAPAN, 2022 VS 2029
  1. Figure 105:  
  2. MOST ACTIVE COMPANIES BY NUMBER OF STRATEGIC MOVES, JAPAN, 2019 - 2021
  1. Figure 106:  
  2. MOST ADOPTED STRATEGIES, COUNT, JAPAN, 2019 - 2021
  1. Figure 107:  
  2. PRODUCTION CAPACITY SHARE OF ENGINEERING PLASTICS BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 108:  
  2. PRODUCTION CAPACITY SHARE OF FLUOROPOLYMER BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 109:  
  2. PRODUCTION CAPACITY SHARE OF LIQUID CRYSTAL POLYMER (LCP) BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 110:  
  2. PRODUCTION CAPACITY SHARE OF POLYAMIDE (PA) BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 111:  
  2. PRODUCTION CAPACITY SHARE OF POLYBUTYLENE TEREPHTHALATE (PBT) BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 112:  
  2. PRODUCTION CAPACITY SHARE OF POLYCARBONATE (PC) BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 113:  
  2. PRODUCTION CAPACITY SHARE OF POLYETHER ETHER KETONE (PEEK) BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 114:  
  2. PRODUCTION CAPACITY SHARE OF POLYETHYLENE TEREPHTHALATE (PET) BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 115:  
  2. PRODUCTION CAPACITY SHARE OF POLYOXYMETHYLENE (POM) BY MAJOR PLAYERS, %, JAPAN, 2022
  1. Figure 116:  
  2. PRODUCTION CAPACITY SHARE OF STYRENE COPOLYMERS (ABS AND SAN) BY MAJOR PLAYERS, %, JAPAN, 2022

Japan Engineering Plastics Industry Segmentation

Aerospace, Automotive, Building and Construction, Electrical and Electronics, Industrial and Machinery, Packaging are covered as segments by End User Industry. Fluoropolymer, Liquid Crystal Polymer (LCP), Polyamide (PA), Polybutylene Terephthalate (PBT), Polycarbonate (PC), Polyether Ether Ketone (PEEK), Polyethylene Terephthalate (PET), Polyimide (PI), Polymethyl Methacrylate (PMMA), Polyoxymethylene (POM), Styrene Copolymers (ABS and SAN) are covered as segments by Resin Type.
End User Industry Aerospace
Automotive
Building and Construction
Electrical and Electronics
Industrial and Machinery
Packaging
Other End-user Industries
Resin Type Fluoropolymer By Sub Resin Type Ethylenetetrafluoroethylene (ETFE)
Fluorinated Ethylene-propylene (FEP)
Polytetrafluoroethylene (PTFE)
Polyvinylfluoride (PVF)
Polyvinylidene Fluoride (PVDF)
Other Sub Resin Types
Liquid Crystal Polymer (LCP)
Polyamide (PA) By Sub Resin Type Aramid
Polyamide (PA) 6
Polyamide (PA) 66
Polyphthalamide
Polybutylene Terephthalate (PBT)
Polycarbonate (PC)
Polyether Ether Ketone (PEEK)
Polyethylene Terephthalate (PET)
Polyimide (PI)
Polymethyl Methacrylate (PMMA)
Polyoxymethylene (POM)
Styrene Copolymers (ABS and SAN)
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Market Definition

  • End-user Industry - Packaging, Electrical & Electronics, Automotive, Building & Construction, and Others are the end-user industries considered under the engineering plastics market.
  • Resin - Under the scope of the study, consumption of virgin resins like Fluoropolymer, Polycarbonate, Polyethylene Terephthalate, Polybutylene Terephthalate, Polyoxymethylene, Polymethyl Methacrylate, Styrene Copolymers, Liquid Crystal Polymer, Polyether Ether Ketone, Polyimide, and Polyamide in the primary forms are considered. Recycling has been provided separately under its individual chapter.
Keyword Definition
Acetal This is a rigid material that has a slippery surface. It can easily withstand wear and tear in abusive work environments. This polymer is used for building applications such as gears, bearings, valve components, etc.
Acrylic This synthetic resin is a derivative of acrylic acid. It forms a smooth surface and is mainly used for various indoor applications. The material can also be used for outdoor applications with a special formulation.
Cast film A cast film is made by depositing a layer of plastic onto a surface then solidifying and removing the film from that surface. The plastic layer can be in molten form, in a solution, or in dispersion.
Colorants & Pigments Colorants & Pigments are additives used to change the color of the plastic. They can be a powder or a resin/color premix.
Composite material A composite material is a material that is produced from two or more constituent materials. These constituent materials have dissimilar chemical or physical properties and are merged to create a material with properties unlike the individual elements.
Degree of Polymerization (DP) The number of monomeric units in a macromolecule, polymer, or oligomer molecule is referred to as the degree of polymerization or DP. Plastics with useful physical properties often have DPs in the thousands.
Dispersion To create a suspension or solution of material in another substance, fine, agglomerated solid particles of one substance are dispersed in a liquid or another substance to form a dispersion.
Fiberglass Fiberglass-reinforced plastic is a material made up of glass fibers embedded in a resin matrix. These materials have high tensile and impact strength. Handrails and platforms are two examples of lightweight structural applications that use standard fiberglass.
Fiber-reinforced polymer (FRP) Fiber-reinforced polymer is a composite material made of a polymer matrix reinforced with fibers. The fibers are usually glass, carbon, aramid, or basalt.
Flake This is a dry, peeled-off piece, usually with an uneven surface, and is the base of cellulosic plastics.
Fluoropolymers This is a fluorocarbon-based polymer with multiple carbon-fluorine bonds. It is characterized by high resistance to solvents, acids, and bases. These materials are tough yet easy to machine. Some of the popular fluoropolymers are PTFE, ETFE, PVDF, PVF, etc.
Kevlar Kevlar is the commonly referred name for aramid fiber, which was initially a Dupont brand for aramid fiber. Any group of lightweight, heat-resistant, solid, synthetic, aromatic polyamide materials that are fashioned into fibers, filaments, or sheets is called aramid fiber. They are classified into Para-aramid and Meta-aramid.
Laminate A structure or surface composed of sequential layers of material bonded under pressure and heat to build up to the desired shape and width.
Nylon They are synthetic fiber-forming polyamides formed into yarns and monofilaments. These fibers possess excellent tensile strength, durability, and elasticity. They have high melting points and can resist chemicals and various liquids.
PET preform A preform is an intermediate product that is subsequently blown into a polyethylene terephthalate (PET) bottle or a container.
Plastic compounding Compounding consists of preparing plastic formulations by mixing and/or blending polymers and additives in a molten state to achieve the desired characteristics. These blends are automatically dosed with fixed setpoints usually through feeders/hoppers.
Plastic pellets Plastic pellets, also known as pre-production pellets or nurdles, are the building blocks for nearly every product made of plastic.
Polymerization It is a chemical reaction of several monomer molecules to form polymer chains that form stable covalent bonds.
Styrene Copolymers A copolymer is a polymer derived from more than one species of monomer, and a styrene copolymer is a chain of polymers consisting of styrene and acrylate.
Thermoplastics Thermoplastics are defined as polymers that become soft material when it is heated and becomes hard when it is cooled. Thermoplastics have wide-ranging properties and can be remolded and recycled without affecting their physical properties.
Virgin Plastic It is a basic form of plastic that has never been used, processed, or developed. It may be considered more valuable than recycled or already used materials.
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  • Step-1: Identify Key Variables: The quantifiable key variables (industry and extraneous) pertaining to the specific product segment and country are selected from a group of relevant variables & factors based on desk research & literature review; along with primary expert inputs. These variables are further confirmed through regression modeling (wherever required).
  • Step-2: Build a Market Model: In order to build a robust forecasting methodology, the variables and factors identified in Step-1 are tested against available historical market numbers. Through an iterative process, the variables required for market forecast are set and the model is built on the basis of these variables.
  • Step-3: Validate and Finalize: In this important step, all market numbers, variables and analyst calls are validated through an extensive network of primary research experts from the market studied. The respondents are selected across levels and functions to generate a holistic picture of the market studied.
  • Step-4: Research Outputs: Syndicated Reports, Custom Consulting Assignments, Databases & Subscription Platforms
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Japan Engineering Plastics Market Research FAQs

How big is the Japan Engineering Plastics Market?

The Japan Engineering Plastics Market size is expected to reach USD 5.72 billion in 2024 and grow at a CAGR of 5.80% to reach USD 7.59 billion by 2029.

What is the current Japan Engineering Plastics Market size?

In 2024, the Japan Engineering Plastics Market size is expected to reach USD 5.72 billion.

Who are the key players in Japan Engineering Plastics Market?

Daicel Corporation, MCT PET Resin Co Ltd, Mitsubishi Chemical Corporation, Sumitomo Chemical Co., Ltd. and Techno-UMG Co., Ltd. are the major companies operating in the Japan Engineering Plastics Market.

Which segment has the biggest share in the Japan Engineering Plastics Market?

In the Japan Engineering Plastics Market, the Electrical and Electronics segment accounts for the largest share by end user industry.

Which is the fastest growing segment in the Japan Engineering Plastics Market?

In 2024, the Electrical and Electronics segment accounts for the fastest growing by end user industry in the Japan Engineering Plastics Market.

What years does this Japan Engineering Plastics Market cover, and what was the market size in 2023?

In 2023, the Japan Engineering Plastics Market size was estimated at 5.72 billion. The report covers the Japan Engineering Plastics Market historical market size for years: 2017, 2018, 2019, 2020, 2021, 2022 and 2023. The report also forecasts the Japan Engineering Plastics Market size for years: 2024, 2025, 2026, 2027, 2028 and 2029.

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Japan Engineering Plastics Market Research

Mordor Intelligence provides a comprehensive analysis of the Japan engineering plastics market. We leverage our extensive expertise in industrial plastics and advanced polymers research. Our detailed report covers the full spectrum of performance plastics, including thermoplastic materials such as polycarbonate, polyamide, ABS plastic, and polyacetal. The analysis includes applications of reinforced plastics and composite plastics, with a focus on heat resistant plastics and high temperature plastics specifications essential for modern manufacturing.

The report is available as an easy-to-download PDF and offers invaluable insights into industrial polymers applications across sectors like automotive plastics, aerospace plastics, and plastics in consumer electronic. We examine the use of structural plastics and durable plastics, including specialty plastics such as PEEK plastic and PPS plastic. Stakeholders benefit from our detailed examination of technical plastics applications in Japan's manufacturing landscape. Our coverage includes everything from thin wall packaging solutions to advanced industrial polymers, enabling informed decision-making and strategic planning in this dynamic market.

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Japan Engineering Plastics Market SIZE & SHARE ANALYSIS - GROWTH TRENDS & FORECASTS UP TO 2029

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