全球工程塑胶市场规模（依最终用途产业、加工技术、应用、地区、范围和预测）

工程塑胶的市场规模及预测

预计工程塑胶市场规模在 2023 年将达到 1,193.2 亿美元，在 2031 年达到 1,735.7 亿美元，2024 年至 2031 年的复合年增长率为 5.5%。

工程塑胶是一种塑胶聚合物，具有比通用塑胶更好的机械性能和热性能。这些材料旨在承受更恶劣的物理和气候条件，是需要高性能的技术应用的理想选择。工程塑胶包括聚碳酸酯、聚酰胺（尼龙）、聚缩醛、聚醚醚酮 (PEEK) 和丙烯腈丁二烯苯乙烯 (ABS)。这些塑料以其强度、耐用性、耐化学性和在宽温度范围内保持品质的能力而闻名。

工程塑胶因其多功能性而被广泛应用于各个领域。在汽车领域，它们用于製造齿轮、轴承和燃油系统，使汽车更轻、更省油。工程塑胶由于其优异的电绝缘性能，在电子工业中用于製造连接器、外壳和绝缘材料。

此外，在医疗产业，工程塑胶因其生物相容性且易于消毒而被用于设备、手术器械、植入物等。其他应用包括飞机、建筑和消费品，这些材料有助于提高性能、耐用性和安全性。

随着各行各业寻求提高性能和可持续性的材料，工程塑胶有望发挥关键作用。聚合物技术和生产技术的进步可能会产生具有强度更高、耐热性更强、环境友善性更强等特性的新型工程塑胶。

工程塑胶的全球市场动态

主要市场驱动因子

汽车产业的成长：汽车产业持续需求轻质、耐用、高性能的材料，这使其成为工程塑胶的主要驱动力。聚酰胺、聚碳酸酯和 PEEK 等工程塑胶用于製造引擎零件、燃油系统和内部组件。这些材料有助于减轻汽车重量、提高燃油经济性并减少污染物。

电气和电子产业的成长：电气和电子产业也是工程聚合物的重要使用者。随着技术的快速发展和消费性电子产品需求的不断增长，对性能更高性能材料的需求也日益增长。工程塑胶具有优异的电绝缘性能、耐热性和尺寸稳定性，广泛应用于製造外壳、连接器等电子元件。随着设备变得越来越紧凑和高效，对聚碳酸酯、PEEK 和 PPS 等高性能材料的需求日益增加。

不断扩大的建筑业：建筑业是工程塑胶市场的主要推动力，尤其是随着人们对永续和节能建筑的偏好日益增长。工程塑胶用于各种建筑应用，包括管道、绝缘材料、玻璃和结构部件。其高强度重量比、耐腐蚀和易于使用等特性使其非常适合现代建筑要求。

监管和安全标准：遵守监管和安全要求对于汽车、航空和医疗保健等行业至关重要。由于其卓越的性能，工程塑胶通常能够满足或超过这些严格的要求。遵守有关安全、排放和环境影响的标准的需求推动了各行各业对工程塑胶的使用。随着监管框架的发展，对确保合规性和安全性的高性能材料的需求仍然很高。

主要问题

环境问题与废弃物管理：工程塑胶对环境的影响是一项重大课题。虽然这些材料有许多好处，但它们也造成了塑胶污染和环境恶化。许多工程塑胶不可生物降解，可以在环境中存留数代。有效的废弃物管理措施，包括回收和处置，是必要的，但往往不够。应对这些课题需要在回收基础设施和可生物降解替代品的开发上进行大量投资。

原料供应有限：另一个问题是工程塑胶中使用的某些原料的供应。许多工程塑胶都是基于石化衍生物，原油供应和价格的波动会影响生产成本和供应安全。此外，一些高性能塑胶需要特定的单体或添加剂，而这些单体或添加剂并不容易取得。这些关键原材料的短缺可能会扰乱供应链并降低企业持续满足需求的能力。为了降低这种风险，需要开发替代的原料来源和合成路线。

加工中的技术课题：加工塑胶可能具有课题性，因为它们需要专门的步骤才能达到所需的品质和性能。由于这些材料的熔点高、黏度问题以及对加工条件的敏感性，它们可能具有课题性。为了实现一致的品质和性能，需要先进的设备和严格的控制技术。加工参数的细微变化都可能导致影响最终产品的机械和热性能的缺陷。解决这些技术课题需要持续投资研发，以及训练有素的人员来监督和优化製造流程。

技术进步与创新：跟上快速的技术进步是一项持续的课题。工程塑胶业务必须不断发展以满足汽车、航空航太和电子等众多终端行业不断变化的需求。这包括开发具有改进的热稳定性、机械强度、耐化学性等的材料。要维持创新领先地位，需要大量研发投入，并与学术界和工业界伙伴合作，以利用尖端技术和见解。

主要趋势

技术进步：持续的技术进步和材料创新正在将工程塑胶拓展到新的应用领域。新兴经济体建筑业的强劲復苏预计将对工程塑胶市场产生积极影响。

更广泛的应用：工程塑胶在非住宅结构中的使用不断增加，特别是在天窗、玻璃和屋顶系统等应用中，预计将推动需求。

具有经济吸引力的市场：由于需求不断增长和新兴应用，工程塑胶市场吸引了许多公司。全球公司和本地公司都在进入不同国家的市场，加剧了竞争并加剧了市场分化。这种竞争格局使得工程塑胶市场特别有吸引力。

目录

第 1 章简介

• 市场定义
• 市场区隔
• 研究方法

第 2 章执行摘要

• 主要发现 市场概况 市集亮点

第三章 市场概览

• 市场规模与成长潜力
• 市场趋势
• 市场推动因素
• 市场限制
• 市场机会
• 波特五力分析

第四章 工程塑胶市场（依最终用途产业）

• 汽车
• 电子电气
• 消费品 航太
• 建筑
• 医疗设备

第五章 工程塑胶市场（依加工技术划分）

• 注塑成型
• 挤压
• 吹塑

第六章 工程塑胶市场（依应用）

• 结构部件
• 功能部件
• 光学元件
• 包装

第 7 章 区域分析

• 北美洲
• 美国
• 加拿大
• 墨西哥
• 欧洲
• 英国
• 德国
• 法国
• 义大利 亚太地区
• 中国
• 日本
• 印度
• 澳大利亚
• 拉丁美洲
• 巴西
• 阿根廷
• 智利
• 中东和非洲
• 南非
• 沙乌地阿拉伯
• 阿拉伯联合大公国

第 8 章 市场动态

• 市场推动因素
• 市场限制
• 市场机会
• COVID-19 对市场的影响

第 9 章 竞争格局

• 大型公司
• 市占率分析

第十章 公司简介

• BASF SE
• The Dow Chemical Company
• DuPont de Nemours, Inc.
• LyondellBasell Industries NV
• SABIC
• Solvay S.A.
• Formosa Plastics Corporation
• Toray Industries, Inc.
• Mitsubishi Chemical Corporation

第 11 章 市场展望与机会

• 新兴技术
• 未来市场趋势
• 投资机会

第 12 章附录

• 缩写列表
• 来源与参考文献

Engineering Plastics Market Size And Forecast

Engineering Plastics Market size was valued at USD 119.32 Billion in 2023 and is projected to reach USD 173.57 Billion by 2031, growing at a CAGR of 5.5% from 2024 to 2031.

Engineering plastics are a class of plastic polymers that have better mechanical and thermal qualities than commodity plastics. These materials are engineered to withstand more demanding physical and climatic conditions, making them ideal for use in technical applications requiring high performance. Engineering plastics include polycarbonates, polyamides (nylons), polyacetals, polyether ether ketone (PEEK), and acrylonitrile butadiene styrene (ABS). These plastics are renowned for their strength, durability, chemical resistance, and ability to retain their qualities across a wide temperature range.

In engineering plastics are used in a wide range of sectors due to their versatility. In the automobile sector, they are utilized to make gears, bearings, and fuel systems, which help to make vehicles lighter and more fuel efficient. Engineering plastics are used in the electronics industry to manufacture connections, housings, and insulation materials due to their superior electrical insulating qualities.

Furthermore, the medical industry uses engineering plastics for equipment, surgical instruments, and implants due to their biocompatibility and simplicity of sterilizing. Other applications include aircraft, construction, and consumer goods, where these materials aid in performance, durability, and safety.

As industries seek materials that improve performance and sustainability, engineering plastics are expected to play an important role. Advances in polymer technology and production techniques are likely to result in new grades of engineering plastics with improved features such as increased strength, stronger temperature resistance, and greater environmental friendliness.

Global Engineering Plastics Market Dynamics

The key market dynamics that are shaping the global Engineering Plastics Market include:

Key Market Drivers:

Automotive Industry Growth: The automobile industry is a significant driver of engineering plastics due to the continued desire for lightweight, durable, and high-performance materials. Engineering plastics such as polyamides, polycarbonates, and PEEK are used to manufacture engine parts, fuel systems, and interior components. These materials help to reduce vehicle weight, which improves fuel efficiency and lowers pollutants.

Growth in the Electrical and Electronics Sector: The electrical and electronics industries are also important users of engineering polymers. With the rapid growth of technology and the growing demand for consumer electronics, there is a greater need for materials with higher performance qualities. Engineering plastics are widely utilized in the production of housings, connectors, and other electronic components due to their superior electrical insulating qualities, heat resistance, and dimensional stability. As devices become more compact and efficient, the demand for high-performance materials such as polycarbonate, PEEK, and PPS increases.

Expansion of the Construction Industry: The construction industry has been a major driver of the Engineering Plastics Market, particularly with the growing preference for sustainable and energy-efficient buildings. Engineering plastics are utilized in a range of construction applications, including piping, insulation, glazing, and structural parts. Their characteristics, including a high strength-to-weight ratio, corrosion resistance, and ease of installation, make them excellent for modern construction requirements.

Regulatory and Safety Standards: Compliance with regulatory and safety requirements is essential in industries such as automobiles, airplanes, and healthcare. Engineering plastics frequently meet or exceed these strict requirements because of their exceptional characteristics. The requirement to follow standards governing safety, emissions, and environmental effects pushes the use of engineering plastics in various industries. As regulatory frameworks evolve, demand for high-performance materials that ensure compliance and safety will remain high.

Key Challenges:

Environmental Issues and Waste Management: The environmental impact of engineering plastics presents a considerable challenge. While these materials provide several benefits, they also contribute to plastic pollution and environmental deterioration. Many engineering plastics are non-biodegradable, which means they can remain in the environment for generations. Effective waste management measures, including recycling and disposal, are necessary yet frequently insufficient. Addressing these challenges necessitates significant investment in recycling infrastructure and the development of biodegradable alternatives.

Limited Availability of Raw Materials: Another problem is the availability of specific raw ingredients used in engineering plastics. Many engineering plastics are based on petrochemical derivatives, and changes in the availability and price of crude oil can affect production costs and supply stability. Furthermore, some high-performance plastics require particular monomers or additives that are not readily available. The lack of these crucial inputs can cause supply chain disruptions, reducing businesses' capacity to meet demand consistently. To mitigate this risk, alternate raw material sources and synthetic routes must be developed.

Technical Challenges in Processing: Processing plastics can be challenging due to the need for specialized processes to attain desired qualities and performance. These materials can provide difficulties due to high melting points, viscosity concerns, and sensitivity to processing conditions. Consistent quality and performance require advanced equipment and strict control techniques. Small changes in processing parameters might cause faults that influence the mechanical and thermal qualities of the finished product. Addressing these technical issues necessitates continual investment in R&D, as well as trained individuals to oversee and optimize manufacturing processes.

Technological Advancement and Innovation: Keeping up with rapid technological advances is an ongoing struggle. The engineering plastics business must develop to suit the changing needs of many end-use industries, including automotive, aerospace, and electronics. This includes creating materials with improved qualities such as increased thermal stability, mechanical strength, and chemical resistance. To stay ahead of the innovation curve, significant research and development expenditure is required, as is engagement with academic institutions and industry partners to exploit cutting-edge technology and insights.

Key Trends:

Technological Advancements: Continued technological advancements and material innovations will enable engineering plastics to expand into new application areas. A robust recovery of the construction industry in developed economies is expected to positively impact the Engineering Plastics Market.

Increasing Application: The increasing use of engineering plastics in non-residential buildings, particularly for applications such as skylights, window glazing, and roofing systems, is anticipated to fuel demand.

Financially Attractive Market: The Engineering Plastics Market is witnessing an influx of players due to increasing demand and emerging applications. Both global and local companies are entering the market across various countries, leading to heightened competition and market fragmentation. This competitive landscape underscores the attractiveness of the Engineering Plastics Market.

Global Engineering Plastics Market Regional Analysis

Here is a more detailed regional analysis of the global Engineering Plastics Market:

North America:

North America has solidified its position as the dominant region in the global Engineering Plastics Market, holding an estimated 35.6% share in 2024.

The United States boasts a robust manufacturing base across key industries like automotive, aerospace, electronics, and healthcare, driving significant demand for engineering plastics. Major players in the automotive and aerospace sectors rely on durable and lightweight plastic components to enhance product performance and meet regulatory standards.

The region benefits from well-established supply chains and distribution networks for engineering plastics, with leading resin producers operating multiple manufacturing facilities in the U.S. and Canada to ensure consistent supply.

The engineers and product designers in North America leverage their expertise in utilizing engineering plastics to develop innovative solutions, collaborating closely with domestic resin suppliers throughout the product development process.

Asia-Pacific:

The Asia Pacific region emerges as the fastest-growing market for engineering plastics, with China leading the charge. China's extensive manufacturing sector and expanding middle class population serve as major catalysts for growth.

The burgeoning domestic automotive industry, coupled with investments from global automakers, drives increased consumption of engineering plastics.

The relocation of electronics production from developed markets to China and other South Asian countries contributes to rising demand from the appliances and consumer goods sectors.

The region's large converter bases, catering to multinational corporations, enhance price competitiveness in manufacturing finished plastic parts. Asia Pacific's favorable low-cost manufacturing environment and proximity to end-use markets further fuel market growth in the region.

Global Engineering Plastics Market: Segmentation Analysis

The Global Engineering Plastics Market is Segmented on the basis of Industry Of End Use, Technology Of Processing, Application, And Geography.

Engineering Plastics Market, By Industry Of End Use

• Automotive
• Electronics And Electrical
• Consumer Goods
• Aerospace
• Construction
• Medical Devices

Based on Industry Of End Use, the market is bifurcated into Automotive, Electronics and Electrical, Consumer Goods, Aerospace, Construction, and Medical Devices. Electronics and Electrical presently encompass the largest proportion of the Engineering Plastics Market, driven by the demand for long-lasting and insulating materials in various electronic components. On the other hand, the Medical Devices segment is expected to be the fastest expanding market. This is due to the growing need for lightweight, sterilizable, and biocompatible engineering polymers in medical devices and implants.

Engineering Plastics Market, By Technology Of Processing

• Injection Moulding
• Extrusion
• Blow Moulding

Based on Technology Of Processing, the market is segmented into Injection Moulding, Extrusion, and Blow Moulding. Injection moulding and blow moulding are not market categories, but rather techniques for shaping engineered polymers. The two most important segmentation parameters for this market are resin type and end user industry. The resin type relates to the exact material utilized, such as nylon or polycarbonate, whereas the end user industry identifies the application, such as automotive or electronics. Typically, the Automotive market is the largest because to the ongoing demand for lightweight, durable parts, and it is predicted to develop further due to the trend of automotive electrification.

Engineering Plastics Market, By Application

• Structural Components
• Functional Parts
• Optical Components
• Packaging

Based on Application, the market is segmented into Structural components, Functional Parts, Optical Components, and Packaging. Structural components vs. functional parts, industry trends indicate that structural components are currently the dominant section of the Engineering Plastics Market. This is most likely owing to engineering plastics' inherent strength and durability, which make them perfect for applications such as car parts and construction materials. Functional parts, on the other hand, are projected to be the fastest expanding segment. This is being driven by rising demand for lightweight, high-performance components in areas such as electronics and consumer appliances.

Key Players

The "Global Engineering Plastics Market" study report will provide valuable insight with an emphasis on the global market. The major players in the market are BASF SE, The Dow Chemical Company, DuPont de Nemours, Inc., LyondellBasell Industries NV, SABIC, Solvay S.A., Formosa Plastics Corporation, Toray Industries, Inc., and Mitsubishi Chemical Corporation. The competitive landscape section also includes key development strategies, market share, and market ranking analysis of the above-mentioned players globally.

Our market analysis also entails a section solely dedicated to such major players wherein our analysts provide an insight into the financial statements of all the major players, along with its product benchmarking and SWOT analysis. The competitive landscape section also includes key development strategies, market share, and market ranking analysis of the above-mentioned players globally.

• Engineering Plastics Market Recent Developments
• In May 2024, Polyplastics, a global leader in engineering plastics, introduced a next-generation polyphenylene sulphide (PPS) grade with significantly enhanced thermal shock resistance. Notably, this new grade can be easily recycled during post-consumer recycling (PCR) without requiring sorting.
• In March 2023, Invibio Biomaterial Solutions, a Victrex plc company, introduced PEEK-OPTIMA AM Filament, an implantable PEEK polymer designed for additive manufacturing.
• In March 2022, Celanese Corporation, a global chemical and specialty materials company, finalized the restructuring of Korea Engineering Plastics Co., enabling Celanese to leverage world-scale polyoxymethylene (POM) polymerization capabilities and bolster the growth of its POM products globally.
• In March 2021, Victrix Plc., a U.K.-based manufacturer, and supplier of high-performance polymers, invested US$1 million in expanding and upgrading the Asia Innovation & Technology Centre (AITC) in Shanghai. This initiative aims to accelerate innovation, streamline time-to-market, and improve the design-to-mass production workflow for advanced engineering designs in Asia.

TABLE OF CONTENTS

1. Introduction

• Market Definition
• Market Segmentation
• Research Methodology

2. Executive Summary

• Key Findings
• Market Overview
• Market Highlights

3. Market Overview

• Market Size and Growth Potential
• Market Trends
• Market Drivers
• Market Restraints
• Market Opportunities
• Porter's Five Forces Analysis

4. Engineering Plastics Market, By Industry Of End Use

• Automotive
• Electronics and Electrical
• Consumer Goods
• Aerospace
• Construction
• Medical Devices

5. Engineering Plastics Market, By Technology Of Processing

• Injection Molding
• Extrusion
• Blow Molding

6. Engineering Plastics Market, By Application

• Structural Components
• Functional Parts
• Optical Components
• Packaging

7. Regional Analysis

• North America
• United States
• Canada
• Mexico
• Europe
• United Kingdom
• Germany
• France
• Italy
• Asia-Pacific
• China
• Japan
• India
• Australia
• Latin America
• Brazil
• Argentina
• Chile
• Middle East and Africa
• South Africa
• Saudi Arabia
• UAE

8. Market Dynamics

• Market Drivers
• Market Restraints
• Market Opportunities
• Impact of COVID-19 on the Market

9. Competitive Landscape

• Key Players
• Market Share Analysis

10. Company Profiles

• BASF SE
• The Dow Chemical Company
• DuPont de Nemours, Inc.
• LyondellBasell Industries NV
• SABIC
• Solvay S.A.
• Formosa Plastics Corporation
• Toray Industries, Inc.
• Mitsubishi Chemical Corporation

11. Market Outlook and Opportunities

• Emerging Technologies
• Future Market Trends
• Investment Opportunities

12. Appendix

• List of Abbreviations
• Sources and References