Illustration detail from a Bakelite Plastics promotional postcard - 1938.

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The Plastic Films Market is experiencing rapid growth driven by rising e-commerce

The plastic films market enjoys widespread applications across various end-use industries such as packaging, agriculture, construction, and electrical & electronics. Plastic films offer several advantages over traditional materials including moisture barrier properties, durability, lightweight and transparency. They are extensively used for flexible packaging of food products, beverages, consumer goods and industrial applications. The growth of e-commerce and online shopping has propelled demand for plastic films from the packaging sector. The Global Plastic Films Market is estimated to be valued at US$157.5 billion in 2024 and is expected to exhibit a CAGR of 7.2% over the forecast period 2024 to 2031. Key Takeaways Key players operating in the plastic films market are Amcor plc, Berry Global Group, Sealed Air Corporation, DuPont, Toray Industries, Jindal Poly Films, RPC Group, and DS Smith. They collectively account for over 30% share of the global market. The Plastic Films Market Demand has been witnessing strong growth globally driven by the expanding food & beverage industry and burgeoning e-commerce sector. Especially in Asia Pacific, growth in the standard of living has boosted consumption of packaged foods and beverages, thereby augmenting plastic films usage. The plastic films market is extending its footprint globally on account of rising export activities from leading producers based in Asia Pacific and Europe. Many developing countries in South America, Middle East & Africa and Asia are emerging as lucrative markets providing ample opportunities for plastic film manufacturers. Market Key Trends One of the key trends gaining momentum in the plastic films market is the increasing replacement of conventional plastics with bioplastics. Bioplastic films made from renewable sources such as cellulose, starch, polylactic acid and polyhydroxyalkanoates offer superior compostability and sustainability. The development of bio-based barrier films, shrink films and stretch films with properties comparable to petroleum-based films will further bolster the adoption of bioplastics in food packaging and other applications over the forecast period.

Porter's Analysis Threat of new entrants: Low capital required for manufacturing plants enables easy entry which increases competition in the market. Bargaining power of buyers: Large number of suppliers in the market gives buyers more options but commodity nature of products limits their power. Bargaining power of suppliers: Major suppliers have established relationships with end-use industry players reducing their individual bargaining power. Threat of new substitutes: Availability of alternative materials like paper and aluminum foils poses threat of substitution to plastic films. Competitive rivalry: Large number of global and regional players operate in a price-sensitive market increasing competition. Geographical Regions North America accounts for the largest share of the plastic films market owing to high demand from various end-use industries like packaging, personal care, construction and others in United States and Canada. Asia Pacific region is expected to grow at the fastest rate during the forecast period due to rapid industrialization and infrastructure development activities in major economies like China and India increasing consumption of plastic films in packaging, agriculture and construction applications.

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About Author:

Money Singh is a seasoned content writer with over four years of experience in the market research sector. Her expertise spans various industries, including food and beverages, biotechnology, chemical and materials, defense and aerospace, consumer goods, etc. (https://www.linkedin.com/in/money-singh-590844163)

How BOROUGE RA140E is Redefining the Landscape of Polymer Science

Rapid changes are occurring in the realm of polymer research, and BOROUGE RA140E is beginning to bring about these changes. This innovative polymer, supplied by leading Virgin Polymer Suppliers in UAE, is revolutionizing the plastics industry with its remarkable properties and applications. This blog article will go over how BOROUGE RA140E is influencing polymer science and why companies that make plastic resin and polymers are opting to collaborate with it.

Expanding BOROUGE RA140E

The exceptional properties of high-performance virgin polymer resin BOROUGE RA140E are well-known. As a raw plastic material, it offers unparalleled strength, durability, and versatility. These characteristics make it a well-liked choice for numerous applications in the plastics sector. BOROUGE RA140E's advanced formulation solves a number of the shortcomings of traditional polymers, paving the way for improvements in product design and manufacturing processes.

Borouge RA140E's Advantages in Polymer Manufacturing Enhanced Robustness and Efficiency

Because BOROUGE RA140E has superior mechanical properties, products made of it are more durable and strong. This feature is crucial for businesses that require high-performance materials that can withstand demanding conditions and heavy use.

Adaptability to Different Uses

Because of its versatility, the BOROUGE RA140E can be used in a variety of industries, including as consumer goods and automotive parts. Owing to its adaptability, it is an essential resource for companies looking to expand and broaden their product line.

The Way BOROUGE RA140E Promotes Environmentally Friendly Behavior

These days, it's becoming more and more important to use greener production techniques, and BOROUGE RA140E stands out for its contribution to this. Since it is a virgin polymer, the environmental impact of its production is minimal, in line with global efforts to reduce waste and promote recycling. Companies that employ BOROUGE RA140E are supporting ecologically beneficial business practices in addition to investing in premium plastics raw materials.

Virgin Polymer Suppliers in UAE Role

Virgin Polymer Suppliers in UAE, like Polymer in Stock, play a significant role in facilitating access to high-quality polymers like BOROUGE RA140E. These suppliers ensure that businesses receive high-quality polymer resin that fulfills their industrial needs and industry regulations. Forming ties with reputable suppliers can help companies stay ahead of industry advancements and provide a consistent source of raw plastic materials.

Future Directions in Polymer Science

As polymer science develops, BOROUGE RA140E is expected to propel innovations. Scientists and manufacturers are exploring new strategies to enhance this polymer's properties and expand its applications. It is anticipated that BOROUGE RA140E will lead the way in polymer science breakthroughs, resulting in further enhancements to material performance, sustainability, and affordability.

To sum up

BOROUGE RA140E is a force for change in the plastics industry, not just a polymer. Its innovative properties and applications are shaping the future of polymer science and opening up new avenues for growth and development. By choosing BOROUGE RA140E, businesses may enhance product performance, encourage sustainable practices, and preserve their competitiveness in a market that is evolving. For those seeking reputable vendors and high-quality virgin polymers to help them achieve their goals, Polymer in Stock is the go-to source.

Polymer Material Testing

Polymer Material Testing and plastic testing lab are among the most versatile materials on the planet, and they are employed in virtually every area of our life. They've changed the way consumer goods and industrial applications like aerospace, automotive, electronics, and packaging are made. Our scientists have the industry expertise to provide you with the information you need to advance product development, assure compliance, and launch a successful market launch for the application you're working on.

Understanding Commodity Plastic: Basics and Applications

Commodity plastic is a term frequently used in the plastics industry to refer to a group of plastics that are produced on a large scale and used in a wide range of applications. Understanding the basics of commodity plastic, including its properties and applications, is essential for anyone involved in the manufacturing or use of plastic products.

Exploring the Basics of Commodity Plastic:

Definition and Characteristics: Commodity Plastic refers to a category of plastics that are produced in high volumes and have relatively low costs compared to engineering plastics or specialty plastics. These plastics are characterized by their versatility, durability, and ease of processing, making them ideal for a variety of applications.

Common Types of Commodity Plastics: Some of the most common types of commodity plastics include polyethylene (PE), polypropylene (PP), polystyrene (PS), polyvinyl chloride (PVC), and polyethylene terephthalate (PET). Each type of commodity plastic has its own unique properties and applications, ranging from packaging materials to consumer goods.

Applications of Commodity Plastic:

Packaging: One of the largest applications of commodity plastic is in packaging materials. Polyethylene and polypropylene, in particular, are widely used for manufacturing plastic bags, bottles, containers, and packaging films due to their excellent barrier properties and flexibility.

Consumer Goods: Commodity plastic is also commonly found in a wide range of consumer goods, including household items, toys, kitchenware, and electronics. Polystyrene, for example, is used to make disposable cups, plates, and food containers, while polyvinyl chloride is used in the production of vinyl flooring and window frames.

Construction Materials: In the construction industry, commodity plastic is used for manufacturing a variety of materials, such as pipes, fittings, insulation, and siding. PVC, in particular, is a popular choice for plumbing and drainage systems due to its corrosion resistance and affordability.

Automotive Components: Commodity plastics play a vital role in the automotive industry, where they are used for manufacturing interior and exterior components, such as dashboards, bumpers, trim panels, and seating. Polypropylene, with its lightweight and impact-resistant properties, is a common choice for automotive applications.

Commodity plastic is a versatile and widely used material that plays a crucial role in various industries and applications. Understanding the basics of commodity plastic, including its properties and applications, is essential for manufacturers, designers, and consumers alike. By recognizing the versatility and value of commodity plastic, we can continue to innovate and create sustainable solutions for the future.

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North America Is Dominating Cold Plasma Industry

In 2022, the cold plasma market recorded a revenue of USD 1,846 million, with a projected compound annual growth rate (CAGR) of 14.80% anticipated from 2022 to 2030. This growth is expected to lead to a market value of USD 5,568 million by 2030, driven by the advantages offered by cold plasma technology across various applications, notably in wound healing, and the continuous advancements in this…

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Plasticizers Market Will Reach USD 24.7 Billion By 2030

The global plasticizers market has garnered USD 17.1 billion in revenue in 2023, and it is projected to rise at the rate of 5.6% from 2023 to 2030, to capture USD 24.7 billion by 2030. Due to the high demand for flexible polymer materials like PVC, the most important end-user for those products is gradually increasing worldwide, i.e., in the construction industry. Furthermore, the surge in the…

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India is currently a powerhouse for plastics and polymer-based products, mainly due to the extensive manufacturing sector in India. The polymer industry in India is expected to grow due to increasing plastic consumption. Read this blog to know the rise of polymer and plastics industry in India

Flexo printing Plastic doctor blades are an essential component of many printing and coating machines. They are used to remove excess ink or coating from the surface of the printing cylinder or anilox roll, ensuring a precise and consistent transfer of ink or coating to the substrate.

Rotogravure printing Plastic doctor blades are typically made from high-quality steels that are hard, wear-resistant, and have excellent edge retention. The most common types of steel used for doctor blades are stainless steel and carbon steel.

The selection of the right Plastic doctor blade depends on the specific application requirements and machine type. Consult with the machine manufacturer or doctor blade supplier for recommendations on the best blade steel for your application.

Plastic Raw Material : Polymers in our Daily Life

All Around us are Polymers which are found in every material in our daily life. The importance of polymers is now rapidly increasing due its various applications in sciences, technologies and industry. Nowadays we cannot imagine a life without polymers. This rapid increase has increased the demand for manufactured products from the raw materials. 

Plastic Raw Material Suppliers in UAE

There are numerous natural and manufactured uses of polymers. As we hear the word Polymers alot lets see what polymers and different types of polymers and its application is in our daily life.

Polymers and Food 

As polymers are part of everyday life, they are most widely used in kitchen applications and food like in the production, packaging and preparation of food. Packaging includes vacuum packaging, insulated packaging and a variety of packaging types.

Polymers and Medical Products

In Opticals, the material of contact lenses was originally made after polymerisation. Also there are several types of polymers which provide biological and physical protection in wound care. In Dental, for fillings the silver and mercury amalgam are replaced by polymeric materials.

Polymers and Sports

In various sporting equipment it includes different types of polymer like athletic footwear in laces, its fabric and synthetic leather contains polymer. In Protective equipment like helmets polymers play a crucial role.

Among the different types of polymers, polypropylene is the highest industrial plastic and Polyethylene Terephthalate is the widely used plastic in the world.

Polyethylene or Polythene

Prominent Plastic Polymer which is further classified into Low Density Polyethylene (LDPE) and High Density Polyethylene (HDPE). The common use of LDPE is to manufacture plastic bags and also used to fabricate containers, dispensing bottles, tubes, and plastic parts in various laboratory equipment. HDPE is a recommended choice in piping due its cost efficiency and corrosion resistance.

Polypropylene or Polypropene

Polypropylene is mainly utilized in fabric industries. Also Engineered in a wide range of packaging from medicine to baby foods. In marine industries also polypropylene is used in various applications as they are strong and moisture resistant.

Polyvinyl Chloride

The thermoplastic material is available in two forms, rigid and flexible. Used as an insulation for electric wires and to manufacture sliding doors and window frames. It also acts as an critical safety role in life saving medicine through IV bags and medical tubing.

Polytetrafluoroethylene or Teflon

Synthetic Fluoropolymer known as Teflon. Its Cost effective feature enables its processing applications from industrial to electric sector. Used in several automotive parts like gaskets, power steering and also used as coatings in tanks, containers, autoclaves etc.

Polymer Supplier in UAE

Since the beginning polymers have been around us like cellulose, starch and natural rubber. Man made polymers came into existence in the mid nineteenth century. Today the Polymer industry has rapidly developed more than Steel and Aluminium Industries. There are synthetic and natural polymers used in inorganic and organic polymer form like coatings, adhesives, plastics and so on. Go Green FZE is a Polymer Company in UAE also specialized as Best Chemicals Suppliers in UAE. Also known for Agricultural Products in UAE and Engineering Plastics Supplier. To Establish Environment friendly nature in Business and Society Go Green FZE globally source polymers, chemicals, and agricultural products with more than 20 years of manufacturing and trading of Plastic and Polymers across the world from warehouses in UAE, Saudi Arabia and Europe at competitive rates meeting customer expectation globally by ensuring the packing and delivery schedule with exemplary range of plastic products. To know more Request for Free Quote with Go Green FZE.

"At the University of Maine, one of the world’s largest 3D printers is using sawdust from the state’s lumber industry to 3D print cozy wooden cabins.

It’s part of a move towards making 3D printing faster and more sustainable in a state where the housing shortage that has metastasized in most states around the country is dire.

It’s thought that 80,000 new homes will be needed over the next 5 years to keep pace with demand, and though it takes years for building codes to be changed, the technicians at the Advanced Structures & Composites Center (ASCC) at the Univ. of Maine hope their new toy can help address this need.

Guinness World Records certified the machine at ASCC as the world’s largest prototype polymer 3D printer, capable of creating a 600 square foot house 96 feet in length, 36 feet in width, and 18 feet tall entirely out of bio-based material at a rate of 500 pounds per hour.

In 2022, it could print the walls, floors, and roof of the house in just 96 hours, but the ACSS has been refining the design with the hope of doubling the printing speed and getting it down to a 48-hour timeline.

“When they’re doing concrete, they’re only printing the walls,” Habib Dagher, the executive director of ACSS told CNN. “The approach we’ve taken is quite different from what you’ve seen, and you’ve been reading about for years.”

Indeed, GNN has reported on a fair number of 3D printing projects, but most if not all involve printing only the walls. One fantastical exception is an Italian firm that is 3D-printing domed, beehive-like, modular concept homes inspired by the Great Enclosure in Zimbabwe.

STAND-OUT 3D-PRINTING PROJECTS: 

First 2-Story Home to be 3D Printed in the U.S. Reaches for the Sky in Texas 

The World’s Largest 3D Printed Building is a Horse Barn That Can Endure Florida Hurricanes

This 23-Year-Old Founder is 3D Printing Schools in Madagascar Aiming to be a ‘Stepping Stone’ for the Community

A Startup Is Using Recycled Plastic to 3D Print Tiny $25,000 Prefabricated Homes in LA

The ASCC is calling the house design the BioHome3D, and says it’s rare people who tour the concept version don’t ask when they “can have one up?”

The interior gives the feel of a modern Scandinavian wooden cabin, making it fit well with the Maine aesthetic. The ASCC is now doing work on how to incorporate conduits for wiring and plumbing “exactly where an architect would want them,” says Dagher.

WATCH a time-lapse video of the printer doing the job…

-via Good News Network, August 16, 2024. Video via The University of Maine, March 3, 2023.

The Global Solidarity Levies Task Force was set up after COP28 and is supported by the UN, World Bank, G20, European Commission, and the African Union. The task force experts have now set out sixteen specific levy ideas for public consultation that could raise billions annually, covering aviation, fossil fuels, carbon pricing, shipping, financial transactions, plastic polymers, cryptocurrencies, and high-net-worth individuals. Some of these taxes already exist in several countries, making a broad international rollout within reach.

According to the Task Force website: “There is a significant gap between current financing and the levels required to meet the 2030 Sustainable Development Goals, the Paris Agreement, and the Global Biodiversity Framework…. [we are] developing options for internationally coordinated levies to help close this gap - ensuring that the most polluting industries and activities that have benefited most from globalisation contribute their fair share.”

On the subject of COP30, it's very good news to know that Brazil has appointed a veteran climate diplomat with no direct ties to the fossil fuel industry to be the next COP president.

For the first time in 3 years, the COP30 president (who plays a crucial role in shaping the agenda and brokering deals) will not hail from the fossil fuel sector. Corrêa do Lago has been Secretary for Climate, Energy and Environment at Brazil’s foreign ministry and Brazil’s chief climate negotiator since 2023.

The Global Solidarity Levies Task Force: For People and the Planet was launched in November 2023 by Barbados, France and Kenya.

It is supported by a Coalition for Solidarity Levies where countries can follow, consult and engage with the task force’s work. These members of the Coalition are Barbados, France, Kenya, Antigua & Barbuda, Colombia, Denmark, Djibouti, Fiji, Marshall Islands, Senegal, Sierra Leone, Somalia, Spain, and Zambia.

How BOROUGE RA140E Is Shaping the Future of Polymer Science

Explore how BOROUGE RA140E is transforming polymer science. Discover insights from Polymer in Stock, a top Virgin Polymer Supplier in the UAE, on its industry impact.

Our planet is choking on plastics. Some of the worst offenders, which can take decades to degrade in landfills, are polypropylene—which is used for things such as food packaging and bumpers—and polyethylene, found in plastic bags, bottles, toys, and even mulch.

Polypropylene and polyethylene can be recycled, but the process can be difficult and often produces large quantities of the greenhouse gas methane. They are both polyolefins, which are the products of polymerizing ethylene and propylene, raw materials that are mainly derived from fossil fuels. The bonds of polyolefins are also notoriously hard to break.

Now, researchers at UC Berkeley have come up with a method of recycling these polymers that uses catalysts that easily break their bonds, converting them into propylene and isobutylene, which are gases at room temperature. Those gases can then be recycled into new plastics.

“Because polypropylene and polyethylene are among the most difficult and expensive plastics to separate from each other in a mixed waste stream, it is crucial that [a recycling] process apply to both polyolefins,” the research team said in a study recently published in Science.

Breaking It Down

The recycling process the team used is known as isomerizing ethenolysis, which relies on a catalyst to break down olefin polymer chains into their small molecules. Polyethylene and polypropylene bonds are highly resistant to chemical reactions, because both of these polyolefins have long chains of single carbon-carbon bonds. Most polymers have at least one carbon-carbon double bond, which is much easier to break.

While isomerizing ethenolysis had been tried by the same researchers before, the previous catalysts were expensive metals that did not remain pure long enough to convert all of the plastic into gas. Using sodium on alumina followed by tungsten oxide on silica proved much more economical and effective, even though the high temperatures required for the reaction added a bit to the cost.

In both plastics, exposure to sodium on alumina broke each polymer chain into shorter polymer chains and created breakable carbon-carbon double bonds at the ends. The chains continued to break over and over. Both then underwent a second process known as olefin metathesis. They were exposed to a stream of ethylene gas flowing into a reaction chamber while being introduced to tungsten oxide on silica, which resulted in the breakage of the carbon-carbon bonds.

The reaction breaks all the carbon-carbon bonds in polyethylene and polypropylene, with the carbon atoms released during the breaking of these bonds ending up attached to molecules of ethylene. “The ethylene is critical to this reaction, as it is a coreactant,” researcher R.J. Conk, one of the authors of the study, told Ars Technica. “The broken links then react with ethylene, which removes the links from the chain. Without ethylene, the reaction cannot occur.”

The entire chain is catalyzed until polyethylene is fully converted to propylene, and polypropylene is converted to a mixture of propylene and isobutylene.

This method has high selectivity—meaning it produces a large amount of the desired product: propylene derived from polyethylene, and both propylene and isobutylene derived from polypropylene. Both of these chemicals are in high demand; propylene is an important raw material for the chemical industry, while isobutylene is a frequently used monomer in many different polymers, including synthetic rubber and a gasoline additive.

Mixing It Up

Because plastics are often mixed at recycling centers, the researchers wanted to see what would happen if polypropylene and polyethylene underwent isomerizing ethenolysis together. The reaction was successful, converting the mixture into propylene and isobutylene, with slightly more propylene than isobutylene.

Mixtures also typically include contaminants in the form of additional plastics. So the team also wanted to see whether the reaction would still work if there were contaminants. They experimented with plastic objects that would otherwise be thrown away, including a centrifuge and a bread bag, both of which contained traces of other polymers besides polypropylene and polyethylene. The reaction yielded only slightly less propylene and isobutylene than it did with unadulterated versions of the polyolefins.

Another test involved introducing different plastics, such as PET and PVC, to polypropylene and polyethylene to see if that would make a difference. These did lower the yield significantly. If this approach is going to be successful, then all but the slightest traces of contaminants will have to be removed from polypropylene and polyethylene products before they are recycled.

While this recycling method sounds like it could prevent tons upon tons of waste, it will need to be scaled up enormously for this to happen. When the research team increased the scale of the experiment, it produced the same yield, which looks promising for the future. Still, we’ll need to build considerable infrastructure before this could make a dent in our plastic waste.

“We hope that the work described … will lead to practical methods for … [producing] new polymers,” the researchers said in the same study. “By doing so, the demand for production of these essential commodity chemicals starting from fossil carbon sources and the associated greenhouse gas emissions could be greatly reduced.”