市场调查报告书
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1466482
生质塑胶市场:按原料、降解性、加工方法和最终用户划分 - 2024-2030 年全球预测Bioplastics Market by Raw Material (Aliphatic Polyesters, Cellulose-Based, Starch-Based), Degradability (Biodegradable, Compostable, Degradable), Processing Method, End-User - Global Forecast 2024-2030 |
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预计2023年生质塑胶市场规模为141亿美元,预计2024年将达159.4亿美元,2030年将达337.2亿美元,复合年增长率为13.25%。
生质塑胶是从植物、微生物和农业废弃物等可再生资源中提取的材料,可取代由石化燃料生产的传统塑胶。它在弹性、耐用性和轻质方面表现出与传统塑胶相似的特性,使其适用于各种应用,包括包装、汽车零件、电子设备、农业和医疗设备。人们对环境问题的日益关注和对塑胶废弃物处理的更严格的监管正在增加对生质塑胶等环保替代品的需求。社会对使用永续产品的认识不断提高也推动了生质塑胶的采用。然而,由于原物料价格、规模经济以及研发投入等原因,生质塑胶的生产成本高于传统塑胶。此外,生质塑胶新应用领域的开发以及性能改进的高性能生物聚合物的研发可能会导致其在各个工业领域的广泛采用。
主要市场统计 | |
---|---|
基准年[2023] | 141亿美元 |
预测年份 [2024] | 159.4亿美元 |
预测年份 [2030] | 337.2亿美元 |
复合年增长率(%) | 13.25% |
对基于纤维素原料的生质塑胶的需求不断增长
脂肪族聚酯是源自玉米和甘蔗等可再生资源的生物分解性、生物相容性聚合物,包括聚乳酸 (PLA) 和聚羟基烷酯(PHA)。这些材料由于其增强的机械性能和环保特性而在包装、农业、纺织和医疗应用等各个行业中广受欢迎。 PLA 广泛用于食品容器等一次性应用,而 PHA 用于製造生物分解性的薄膜。纤维素生质塑胶由植物来源的纤维素纤维製成,具有高拉伸强度和优异的氧气和水蒸气阻隔性,包括醋酸纤维素(CA)、醋酸丁酸纤维素(CAB)和玻璃纸薄膜。这些材料在透明度和弹性很重要的应用中是首选,例如眼镜框和柔性食品包装解决方案。淀粉基塑胶是透过将淀粉与其他生物聚合物混合来生产的,以提高机械性能。这些材料具有优异的成膜能力,适用于可堆肥之前寿命较短的应用,例如购物袋和农业地膜。甘蔗生物生质塑胶,主要是生质乙醇衍生的聚乙烯(PE),是以甘蔗为原料製造的。它具有与传统 PE 类似的特性,可用于消费品包装、汽车零件和建筑材料等应用。脂肪族聚酯用途广泛且生物分解性。 PLA 由于其与各种加工技术更好的兼容性而获得了广泛的市场认可。纤维素基生质塑胶因其透明性和弹性而广受欢迎,而淀粉基材料则用于短寿命应用。甘蔗衍生的生物 PE 为传统石化塑胶提供了更永续的替代品,且不会影响性能或应用。
可降解性:可堆肥生质塑胶
生物分解性的生质塑胶旨在透过微生物的作用自然分解为水、二氧化碳和生物质。这些材料非常适合需要或希望在自然环境中处置的应用。常见的生物分解性的生质塑胶包括聚羟基烷酯(PHA)、聚乳酸(PLA)和Polybutylene丁二醇酯(PBS)。可堆肥生质塑胶是生物分解性塑胶的一个子类,在特定的堆肥条件下,在一定时间内完全分解,并且不会留下有毒残留物。这些材料符合严格的标准,可以进行工业堆肥。可堆肥生质塑胶适用于刀叉餐具、盘子和杯子等食品服务用品,以及用于收集有机废弃物的可堆肥袋。可分解塑胶是可以透过物理或化学过程分解的塑料,但不一定来自可再生资源或分解成对环境安全的产品。可氧化可分解塑胶和光分解性塑胶通常以石油为基础,并经过添加剂处理,使其能够在某些条件下降解,例如暴露于热、光或氧气。生物分解性和可堆肥的生质塑胶提供了比可分解塑胶更环保的选择,因为它们分解成无害的产品,并且不会造成微塑胶污染。
加工方法:射出成型在生质塑胶生产上日益普及
挤出是一个连续过程,其中粒状或粉末状生质塑胶原料被熔化并被迫透过成型晶粒来生产薄膜、片材、管材、型材和纤维。在生产包装材料、建筑零件、汽车零件和纺织产品时,优选此方法。挤压成型是大规模生产的理想选择,模具成本相对较低。可以进行具有独特截面形状的灵活设计,并且可以不受尺寸限制地连续生产。射出成型涉及在高压下将熔融生质塑胶材料注射到所需最终产品形状的模腔中。射出成型常用于製造汽车零件、家用电器、家电机壳、玩具、医疗设备、一次性餐具等。射出成型可以精确控制设计细节,具有高表面光洁度品质和尺寸精度。挤压成型成型适用于更简单的几何形状和大型连续应用,而射出成型复杂的设计提供更高的精度和弹性。
最终用户:扩大生质塑胶在医疗保健领域的使用
在农业领域,出于环境和经济考虑,例如减少塑胶废弃物和提高农业永续性,对生质塑胶的需求不断增加。生物分解性的地膜、种子披衣、麻线、木桩等是生质塑胶在农业的应用。汽车製造商越来越多地采用生质塑胶来减轻汽车重量、减少碳排放并促进永续性。 PLA 和生物基聚酰胺等生物聚合物应用于座垫和仪表板零件等内装零件。消费品製造商正在电子、个人保健产品和玩具产业中采用生质塑胶作为永续包装解决方案。生质塑胶越来越多地应用于医疗保健领域,包括医疗设备、植入和一次性产品。原因是生物相容性和减少碳足迹。由于消费者需求和对传统塑胶永续替代品的监管压力,包装产业是生质塑胶的最大消费者。典型应用包括食品包装、饮料瓶、购物袋和生物分解性薄膜。生质塑胶在纺织业中发挥重要作用,因为它们生物分解性,并且比聚酯和尼龙等合成纤维对环境的影响更低。应用范围广泛,包括含有聚乳酸 (PLA) 的服饰纤维和鞋类零件。
区域洞察
由于对永续性和减少塑胶污染的强烈关注,以及对创新生质塑胶解决方案研发 (R&D) 的投资,生质塑胶市场正在美洲发展。在循环经济措施以及鼓励生质塑胶创新的政策和法律实施的推动下,欧洲、中东和非洲地区正在成为多元化的新兴生质塑胶经济体。非洲目前在生质塑胶的全球市场占有率较小,但由于消费者对环境问题的认识不断提高以及地区政府针对一次性塑胶的政策倡议,因此存在相当大的成长潜力。亚太地区的生质塑胶正在快速发展,主要集中在减少塑胶废弃物,从而导致对生物分解性材料的需求增加。此外,随着生质塑胶3D列印技术的进步和医疗保健应用的扩大,全球对生质塑胶的需求预计将扩大。
FPNV定位矩阵
FPNV定位矩阵对于评估生质塑胶市场至关重要。我们检视与业务策略和产品满意度相关的关键指标,以对供应商进行全面评估。这种深入的分析使用户能够根据自己的要求做出明智的决策。根据评估,供应商被分为四个成功程度不同的像限:前沿(F)、探路者(P)、利基(N)和重要(V)。
市场占有率分析
市场占有率分析是一种综合工具,可以对生质塑胶市场供应商的现状进行深入而详细的研究。全面比较和分析供应商在整体收益、基本客群和其他关键指标方面的贡献,以便更好地了解公司的绩效及其在争夺市场占有率时面临的挑战。此外,该分析还提供了对该行业竞争特征的宝贵见解,包括在研究基准年观察到的累积、分散主导地位和合併特征等因素。这种详细程度的提高使供应商能够做出更明智的决策并制定有效的策略,从而在市场上获得竞争优势。
1. 市场渗透率:提供有关主要企业所服务的市场的全面资讯。
2. 市场开拓:我们深入研究利润丰厚的新兴市场,并分析其在成熟细分市场的渗透率。
3. 市场多元化:提供有关新产品发布、开拓地区、最新发展和投资的详细资讯。
4. 竞争评估和情报:对主要企业的市场占有率、策略、产品、认证、监管状况、专利状况和製造能力进行全面评估。
5. 产品开发与创新:提供对未来技术、研发活动和突破性产品开发的见解。
1、生质塑胶市场规模及预测如何?
2.生质塑胶市场预测期内需要考虑投资的产品、细分市场、应用和领域有哪些?
3.生质塑胶市场的技术趋势和法规结构是什么?
4.生质塑胶市场主要厂商的市场占有率是多少?
5. 进入生质塑胶市场的适当型态和策略手段是什么?
[181 Pages Report] The Bioplastics Market size was estimated at USD 14.10 billion in 2023 and expected to reach USD 15.94 billion in 2024, at a CAGR 13.25% to reach USD 33.72 billion by 2030.
Bioplastics are materials derived from renewable sources such as plants, microorganisms, and agricultural waste that can function as alternatives to conventional plastics produced from fossil fuels. They exhibit similar properties to traditional plastics regarding flexibility, durability, and lightweight performance, making them suitable for various applications in packaging, automotive components, electronics, agriculture, and medical devices. Increasing environmental concerns and stricter regulations regarding plastic waste disposal have led to a higher demand for eco-friendly alternatives such as bioplastics. Rising public awareness about using sustainable products also drives the adoption of bioplastics. However, the production cost of bioplastics is higher than that of conventional plastics due to feedstock prices, economies of scale, and investment in research & development. Moreover, the development of new application areas for bioplastics and research to develop high-performance biopolymers with enhanced properties can broaden their adoption across various industries.
KEY MARKET STATISTICS | |
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Base Year [2023] | USD 14.10 billion |
Estimated Year [2024] | USD 15.94 billion |
Forecast Year [2030] | USD 33.72 billion |
CAGR (%) | 13.25% |
Raw Material: Proliferating demand for cellulose-based bioplastics
Aliphatic polyesters are biodegradable and biocompatible polymers derived from renewable resources, including corn or sugarcane, and include polylactic acid (PLA) and polyhydroxyalkanoates (PHA). These materials have gained popularity in various industries, including packaging, agriculture, textiles, and medical applications, due to their enhanced mechanical properties and eco-friendly nature. PLA is widely used for single-use disposable items such as food containers, whereas PHA is utilized in the production of biodegradable films. Cellulose-based bioplastics are derived from plant-derived cellulose fibers, which offer high tensile strength and good barrier properties against oxygen and water vapor and include cellulose acetate (CA), cellulose acetate butyrate (CAB), and cellophane films. These materials are preferred in applications where transparency or flexibility is important, such as eyewear frames or flexible packaging solutions for food products. Starch-based plastics are manufactured by blending native starch with other biopolymers to improve their mechanical properties. These materials show excellent film-forming capabilities, making them suitable for uses such as shopping bags or agricultural mulch films that require a short service life before becoming compostable. Sugarcane-based bioplastics, primarily polyethylene (PE) derived from bioethanol, are produced using sugarcane as a feedstock. It exhibits similar properties to conventional PE and is used in applications such as consumer goods packaging, automotive components, and construction materials. Aliphatic polyesters have versatile applications and inherent biodegradability. PLA has enhanced compatibility with various processing techniques and widespread market acceptance. Cellulose-based bioplastics are popular for their transparency and flexibility, while starch-based materials are used in short-service life applications. Sugarcane-derived Bio-PE offers a more sustainable alternative to traditional petrochemical plastics without compromising performance or application scope.
Degradability: Significant penetration of compostable bioplastics
Biodegradable bioplastics are designed to break down naturally into water, carbon dioxide, and biomass under the action of microorganisms. These materials are ideal for applications where disposal in natural environments is required or preferred. Some common biodegradable bioplastics include Polyhydroxyalkanoates (PHA), Polylactic Acid (PLA), and Polybutylene Succinate (PBS). Compostable bioplastics are a subcategory of biodegradable plastics that decompose entirely under specific composting conditions within a set time frame, leaving no toxic residues behind. These materials meet strict standards and can be industrially composted. Compostable bioplastics are well-suited for food service items, such as cutlery, plates, and cups, as well as compostable bags used for collecting organic waste. Degradable plastics break down through physical or chemical processes; however, they may not necessarily be derived from renewable resources or decompose into environmentally safe byproducts. Oxodegradable plastics and photodegradable plastics are often petroleum-based and treated with additives that enable fragmentation under specific conditions, such as exposure to heat, light, or oxygen. Biodegradable and compostable bioplastics offer more environmentally friendly options than degradable plastics, as they decompose into harmless byproducts and do not contribute to microplastic pollution.
Processing Method: Growing popularity of injection molding in bioplastic manufacturing
Extrusion is a continuous process where raw bioplastic materials, in the form of pellets or powder, are melted and forced through a shaping die to produce films, sheets, tubes, profiles, and fibers. This method is preferred when manufacturing packaging materials, construction components, automotive parts, and textiles. Extrusion is ideal for large-scale production with relatively low tooling costs. It allows for flexible designs with unique cross-sectional shapes and permits continuous production without size limitations. Injection molding involves injecting molten bioplastic material under high pressure into a mold cavity shaped as the desired end product. It's commonly used for producing automotive components, household appliances, consumer electronics enclosures, toys, medical devices, and disposable cutlery. Injection molding offers precise control over design details with high surface finish quality and dimensional accuracy. Extrusion caters to simpler geometries and larger continuous applications, while injection molding provides higher precision and flexibility for intricate designs.
End-User: Expanding applications of bioplastics in healthcare
The agriculture sector has a growing need for bioplastics due to environmental and economic concerns, including reducing plastic waste and raising the sustainability of agricultural practices. Biodegradable mulch films, seed coatings, twine, and stakes are bioplastic applications in agriculture. Automakers increasingly prefer bioplastics as they aim to reduce vehicle weight, decrease carbon emissions, and promote sustainability. Biopolymers such as PLA or bio-based polyamides find applications in interior parts such as seat cushions and dashboard components. Consumer goods manufacturers adopt bioplastics for sustainable packaging solutions across electronics, personal care products, and toy industries. Bioplastics are increasingly utilized in the healthcare sector for applications, including medical devices, implants, and disposable products. The preference stems from their biocompatibility and reduced carbon footprint. The packaging industry is the largest consumer of bioplastics due to consumer demand and regulatory pressure for sustainable alternatives to traditional plastics. Key applications include food packaging, beverage bottles, shopping bags, and biodegradable films. Bioplastics play a significant role in the textile industry due to their biodegradability and reduced environmental impact compared to synthetic fibers such as polyester or nylon. Applications range from clothing fibers, including polylactic acid (PLA), and footwear components.
Regional Insights
The bioplastic market is evolving in the Americas with a strong focus on sustainability and reducing plastic pollution and investments in research and development (R&D) for innovative bioplastic solutions. The Europe, Middle East, and Africa region exhibits a varied landscape for bioplastics development owing to the efforts towards a circular economy by implementing policies and introducing legislation encouraging innovation in bioplastics. Africa, though currently having a small share of the global bioplastics market, offers considerable growth potential due to increasing consumer awareness of environmental concerns and regional governments' policy initiatives against single-use plastics. The Asia Pacific region is witnessing rapid bioplastic advancements, primarily owing to the focus on reducing plastic waste, leading to growing demand for biodegradable materials. Besides, ongoing 3D printing of bioplastics and expanding applications in healthcare are anticipated to boost the demand for bioplastics worldwide.
FPNV Positioning Matrix
The FPNV Positioning Matrix is pivotal in evaluating the Bioplastics Market. It offers a comprehensive assessment of vendors, examining key metrics related to Business Strategy and Product Satisfaction. This in-depth analysis empowers users to make well-informed decisions aligned with their requirements. Based on the evaluation, the vendors are then categorized into four distinct quadrants representing varying levels of success: Forefront (F), Pathfinder (P), Niche (N), or Vital (V).
Market Share Analysis
The Market Share Analysis is a comprehensive tool that provides an insightful and in-depth examination of the current state of vendors in the Bioplastics Market. By meticulously comparing and analyzing vendor contributions in terms of overall revenue, customer base, and other key metrics, we can offer companies a greater understanding of their performance and the challenges they face when competing for market share. Additionally, this analysis provides valuable insights into the competitive nature of the sector, including factors such as accumulation, fragmentation dominance, and amalgamation traits observed over the base year period studied. With this expanded level of detail, vendors can make more informed decisions and devise effective strategies to gain a competitive edge in the market.
Key Company Profiles
The report delves into recent significant developments in the Bioplastics Market, highlighting leading vendors and their innovative profiles. These include Arkema S.A., Avantium N.V, BASF SE, Bewi Group, Bio-on S.p.A., Biome Bioplastics Limited, Braskem SA, Carbios, Celanese Corporation, Clondalkin Group Holdings B.V., Danimer Scientific, Eastman Chemical Company, FKuR Kunststoff GmbH, GC International by PTT Global Chemical PLC, Good Natured Products Inc., Green Dot Bioplastics Inc., Ilkwang Polymer Co.,Ltd., Kuraray Co., Ltd., Mitsubishi Chemical Corporation, Natur-Tec by Northern Technologies International Corporation, NatureWorks LLC, Neste Oyj, Novamont SpA, Plantic Technologies Ltd., Roquette Freres, TianAn Biologic Materials Co., Ltd., Toray Industries Inc., TotalEnergies Corbion BV, and UrthPact, LLC.
Market Segmentation & Coverage
1. Market Penetration: It presents comprehensive information on the market provided by key players.
2. Market Development: It delves deep into lucrative emerging markets and analyzes the penetration across mature market segments.
3. Market Diversification: It provides detailed information on new product launches, untapped geographic regions, recent developments, and investments.
4. Competitive Assessment & Intelligence: It conducts an exhaustive assessment of market shares, strategies, products, certifications, regulatory approvals, patent landscape, and manufacturing capabilities of the leading players.
5. Product Development & Innovation: It offers intelligent insights on future technologies, R&D activities, and breakthrough product developments.
1. What is the market size and forecast of the Bioplastics Market?
2. Which products, segments, applications, and areas should one consider investing in over the forecast period in the Bioplastics Market?
3. What are the technology trends and regulatory frameworks in the Bioplastics Market?
4. What is the market share of the leading vendors in the Bioplastics Market?
5. Which modes and strategic moves are suitable for entering the Bioplastics Market?