Bio-Based Plasticizers: a Sustainable Approach to
- Classification:Chemical Auxiliary Agent, Chemical Auxiliary Agent
- Other Names:Plasticizer
- Purity:99%min
- Type:Plastizer
- Usage:Chemical Auxiliary Agent, Leather Auxiliary Agents
- MOQ:25kg/bag
- Package:200kg/drum
- Application:PVC Plasticizer
According to Grandview Research’s market report, the market size in the U.S. was estimated at USD 3.05 billion in 2023.Anticipating a substantial growth trajectory of 8.7% (CAGR) from 2024 to 2030. Bio-based plasticizers
Synthesis and Evaluation of Bio-Based Plasticizers from 5-Hydroxymethyl-2-Furancarboxylic Acid for Poly(vinyl chloride). Industrial & Engineering Chemistry Research 2020, 59 Development of biobased
Opportunities and Challenges in the Application of
- Classification:Chemical Auxiliary Agent, Chemical Auxiliary Agent
- Other Names:Plasticizer
- Purity:99%, 99%
- Type:Plasticizer
- Usage:Coating Auxiliary Agents, Electronics Chemicals, Leather Auxiliary Agents, Paper Chemicals, Plastic Auxiliary Agents
- MOQ:200kgs
- Package:200kgs/battle
- Sample:Availabe
- Application:Plasticizer
- Quality control:COA ,SDS,TDS
- Delivery:Within 7-15 Days
Tremendously negative effects have been generated in recent decades by the continuously increasing production of conventional plastics and the inadequate management
Generally, plasticizers are added to both synthetic and bio-based polymeric materials to impart flexibility, improve toughness, and lower the glass transition temperature. This review introduces the most common bio-based plastics and
The Rise of Bio-Plasticizers in PVC Polymer Technologist
- Classification:Chemical Auxiliary Agent, Chemical Auxiliary Agent
- Other Names:Plasticizer
- Purity:99%
- Type:Plasticizer, Dioctyl Phthalate
- Usage:Leather Auxiliary Agents, Paper Chemicals, Petroleum Additives, Plastic Auxiliary Agents, Rubber Auxiliary Agents, Textile Auxiliary Agents, Leather Auxiliary Agent,Plastic Auxiliary Agent,
- MOQ:25kg/bag
- Package:200kg/drum
- Type:Adsorbent
The increasing environmental concerns and health risks associated with traditional plasticizers have led to a significant shift towards bio-based alternatives, particularly in the
Vegetable oil-based plasticizers. Vegetable oils such as soybean oil, peanut oil, castor oil, tung oil, palm oil and so on which are generally extracted from plant seeds and germ, are widely distributed in nature [].The main components of
Development, influencing parameters and interactions of
- Classification:Chemical Auxiliary Agent, Chemical Auxiliary Agent
- Other Names:Plasticizer
- Purity:99.99, 99%
- Type:Plasticizer, Dioctyl Phthalate
- Usage:Coating Auxiliary Agents, Leather Auxiliary Agents, Plastic Auxiliary Agents, Rubber Auxiliary Agents
- MOQ:200kgs
- Package:200kgs/battle
- Shape:Powder
- Place of Origin::China
- Item:T/T,L/C
The goal of this review is to design an ultimate bio-based plasticizer for rubber that fulfills all the requirements of an efficient plasticizer and to elaborate the multidisciplinary
In the last two decades, the use of phthalates has been restricted worldwide due to their well-known toxicity. Nonetheless, phthalates are still widely used for their versatility, high plasticization effect, low cost, and lack of valuable alternatives.
A targeted review of bio-derived plasticizers with flame
- Classification:Chemical Auxiliary Agent
- Other Names:Plasticizer
- Purity:99%, 99%
- Type:Plastic Auxiliary Agents
- Usage:Leather Auxiliary Agents, Plastic Auxiliary Agents, Plasticizer
- MOQ:200kgs
- Package:200kgs/battle
- Application:PVC Plasticizer
This focused review presents current research in the flexible PVC field emphasizing development of bio-plasticizers and flame retardants, and an analysis of examples of bio-plasticizers, chemical structures, and effects on flame retardancy. In the area of bio-based plasticizer, epoxidized soybean oil (ESO) has been in use to partially
Growing awareness of the effects of plasticizers on the environment and the depletion of petroleum-based resources has made the development of an alternative biobased plasticizer for PVC formulation necessary. Recently, there has been an increased consciousness of the use of natural resource-based plasticizers instead of phthalates in PVC
- Why are bio-based plasticizers important?
- The rapid technological development of bio-based plastics, such as PLA, polyhydroxyalkanoates, (PHA), bio-based epoxy resin and bio-based PE, has yet to be translated into significant market impact, primarily due to high production cost and performance limitations. Plasticizers are important additives and performance enhancers of polymers.
- Is there a biobased plasticizer for PVC formulation?
- Growing awareness of the effects of plasticizers on the environment and the depletion of petroleum-based resources has made the development of an alternative biobased plasticizer for PVC formulation necessary.
- What is a bio-based plasticizer?
- Minjia Lu, Pingping Jiang, Pingbo Zhang, Shan Feng, Zhixuan Cui, Qingkui Song, Yong Zhao. A highly stable bio-based plasticizer constructed from renewable acids for plasticizing and enhancing the optical properties of poly (vinyl chloride).
- Are plasticizers compatible with bio-based plastics?
- Plasticizers have long been known for their effectiveness in enhancing the flexibility of synthetic plastics such as polyvinyl chloride (PVC) and epoxy resins. New types of plasticizers compatible with bio-based plastics are being developed.
- What role could bio-based plastics play in a bioeconomy?
- To identify the role bio-based plastics could potentially have in a bioeconomy, it is important to determine the sustainability of bio-based plastics on a global scale. This could serve as a basis to guide future technology developments of bio-based plastics to the most sustainable path.
- What is the global production capacity for bio-based plastics?
- In 2014, the global production capacities for bio-based plastics made up approximately 1.48 million tonnes with a share of about 70% durable and 30% degradable materials (IfBB, 2015).