Exploring the FEP Heat Shrink Medical Tubing Market: Growth, Applications, and Future Prospects

The FEP (Fluorinated Ethylene Propylene) Heat Shrink Medical Tubing market is experiencing robust growth, spurred by innovations in healthcare, a shift toward minimally invasive devices, and the need for safe, biocompatible materials. FEP tubing is valued for its chemical resistance, flexibility, and transparency, which make it ideal for various applications within the medical industry. FEP Heat Shrink Medical Tubing Market is estimated to be USD 145 million in 2024, and it is projected to reach USD 208 million by 2029 at a CAGR of 7.4%.

Key Features of FEP Tubing

FEP is a fluoropolymer known for its exceptional durability under challenging conditions. When heat-shrunk, FEP tubing conforms to underlying components, adding a protective layer around medical devices. Key properties include:

Biocompatibility: Minimizes the risk of reactions, ensuring safe interaction with human tissue.

Chemical and Thermal Stability: Essential for protecting sensitive components against chemical exposure and high temperatures.

Transparency and Smoothness: Allows medical professionals to monitor fluids within the device while also ensuring easy device insertion.

Key Applications

FEP heat shrink tubing is indispensable across various medical applications:

Catheters: Acts as a durable, smooth protective layer that navigates the body’s complex pathways while shielding sensitive inner wiring.

Endoscopic Instruments: Offers protection from chemical exposure and maintains structural integrity through sterilization cycles.

Electrosurgical Devices: Adds a layer of safety by insulating electrically conductive parts.

Encapsulation for Wires and Sensors: Safeguards sensors in monitoring equipment, especially those exposed to harsh environments.

Market Growth Drivers

Several factors drive the demand for FEP heat shrink tubing:

Rising Demand for Non-invasive Procedures: As minimally invasive methods become the norm, demand for high-quality, durable tubing has risen.

Medical Device Innovations: FEP tubing supports next-generation devices by enabling flexible, strong material integration.

Adherence to Global Standards: FEP tubing’s compliance with strict international health standards boosts its usage in the healthcare sector.

Healthcare Expansion in Emerging Markets: Increased global access to healthcare is driving demand for high-quality medical equipment.

Market Challenges

While FEP tubing holds a strong market position, it faces challenges. Competing materials like PTFE offer similar benefits, so careful material selection is essential for manufacturers. Additionally, FEP is a costly material due to its specialized manufacturing process, which can impact product pricing.

Future Market Directions

Advances in medical technologies suggest a bright future for FEP tubing. Emerging trends include:

New Material Blends: Manufacturers are experimenting with FEP hybrids for enhanced performance.

Wearable Medical Devices: As healthcare becomes increasingly wearable, the need for flexible, durable materials like FEP is set to grow.

Eco-conscious Production: With environmental sustainability in focus, manufacturers are also exploring greener production practices.

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The FEP heat shrink medical tubing market is poised for expansion, especially as healthcare devices continue to evolve. Its properties make FEP tubing a valuable asset to medical innovation, and manufacturers that focus on both quality and sustainability will likely see success in this competitive landscape. For those in the industry, staying updated on FEP advancements can provide an edge in developing next-gen medical devices that balance functionality, safety, and efficiency.

How to choose the right heat shrink tubing for your surplus electronic parts

In the world of electronics, managing surplus electronic parts is a common practice, and having the right tools and materials is crucial. One often-overlooked component is heat shrink tubing, which plays a vital role in protecting and insulating wires and components. When it comes to choosing the right heat shrink tubing for your surplus electronic parts, it's essential to consider various factors to ensure a seamless and reliable application.

Size Matters: Surplus parts come in various sizes, so selecting the right heat shrink tubing size is paramount. Measure the diameter of the component or wire you need to cover and choose tubing with a diameter slightly larger to allow for a snug fit once heated.

Shrink Ratio: Heat shrink tubing comes with different shrink ratios, indicating how much it will shrink when heated. Common ratios include Ensure the tubing's shrink ratio matches your needs for a secure and tight fit.

Material and Environment: Consider the environment where your surplus electronic parts will be used. Heat shrink tubing is available in various materials, including polyolefin, PVC, and fluorinated ethylene propylene (FEP). Each material offers different properties such as temperature resistance and flexibility, so choose one that suits your application.

Adhesive-Lined Tubing: For added protection against moisture and contaminants, opt for adhesive-lined heat shrink tubing. This type forms a watertight seal when heated, perfect for outdoor or harsh environments.

Color Coding: If you need to identify different wires or components easily, select heat shrink tubing in various colors. This aids in organization and simplifies troubleshooting.

When searching for heat shrink tubing, you can rely on reputable surplus electronic parts suppliers like Expediters.com. They offer a wide range of heat shrink tubing options suitable for various applications. Remember that choosing the right heat shrink tubing is essential for maintaining the integrity of your surplus electronic parts and ensuring their longevity. By considering these factors, you'll be well-equipped to make an informed decision and keep your electronics in top-notch condition.

Fluoropolymer Market Demand, Size & Forecast to 2030

Market Scope & Overview

A variety of exploratory research methodologies, including primary and secondary research, were used to create an analytical picture of the market. The study report is a trustworthy resource for market participants because it contains a wide range of business information, such as major geographic areas, global market participants, opportunities, triggers, limits, and obstacles. The Fluoropolymers Market research provides current information on the state of the local and international markets. This research study was developed with the help of extensive analysis, original research interviews, and secondary research data.

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The global research report contains perspectives from executives at various stages of the consumer value chain, as well as a quantitative and qualitative analysis of data gathered by corporate professionals. The Fluoropolymers market research report covers a wide range of topics, such as recent technological developments, global industry trends, market size and share, and emerging technologies.

Market Segmentation Analysis

The Fluoropolymers market research examines a variety of topics, such as products, end users, and geographic locations. The primary suppliers and customers are identified in the market research study. The research looks into the market's size, growth rates, and the current and future performance of key applications. The examination considers the attractiveness of the key segments over the forecasted time period. The research report categorizes the world economy based on three characteristics: infrastructure, location, and application.

Market Segmentation:

By Type

Polytetrafluoroethylene (PTFE)

Polyvinylidene Fluoride (PVDF)

Fluoroelastomers (FKM)

Fluorinated Ethylene-Propylene (FEP)

Ethylene Tetrafluoroethylene (ETFE)

Polychlorotrifluoroethylene (PCTFE)

Others

By Application

Coatings

Films & Sheets

Tubes

Additives

Others

By End-Use Industry

Chemical Processing

Automotive

Electrical and Electronics

Building and Construction

Industrial Equipment

Medical

Household

Others

Key players:

The Key Players are AGC Chemicals Americas, Inc., Huntsman Corporation, Dongyue Group Ltd., Poly Fluoro Ltd., Solvay SA, The Chemour Company, Honeywell International Inc., Daikin Industries Limited, Kureha Corporation, Amco Polymers, Saint-Gobain Performance Plastics & Other Players

Russia-Ukraine Conflict Impact Analysis

The Fluoropolymers research report investigates the impact of the Russia-Conflict dispute on various areas and markets. Furthermore, the report includes case studies of various market participants involved in such a conflict.

Regional Outlook

The Fluoropolymers market research also provides a variety of simple visual aids and authentic statistical data that show the proportions of various service providers in various regional markets such as Asia Pacific, Europe, North America, Latin America, and the Middle East and Africa.

Competitive Analysis

The research report includes detailed profiles of the top market participants, as well as information on any notable recent events or activities that have provided them with a competitive advantage. To gain a better understanding of the Fluoropolymers market, the most recent research study evaluates micro and macro statistics, as well as current and expected changes in the global economy in the near future.

Key Reasons to Purchase Fluoropolymers Market Report

In-depth research, market predictions, trends, opportunities and challenges, growth factors, and vendor information are all included in global industry studies.

The report is a reliable source of information and support because it provides vital industry statistics.

A global industry investigation includes significant breakthroughs, brand descriptions, product features, contact information, and other facts.

Conclusion

The Fluoropolymers market research report contains a long-term forecast, current trends and drivers, and an up-to-date analysis of the industry's expanding global structure.

Table of Contents

 1. Introduction

2. Research Methodology

3. Market Dynamics

4. Impact Analysis

5. Value Chain Analysis

 6. Porter’s 5 forces model

 7.  PEST Analysis

 8. Global Fluoropolymers Market Segment, By Type

9. Global Fluoropolymers Market Segment, By Application

10. Global Fluoropolymers Market Segment, By End-Use Industry

11. Regional Analysis

12. Company Profile

13. Competitive Landscape

14. Conclusion

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Heat-Shrink Tubing Market is Predicted to See Lucrative Gains Over 2022-2028

The report on the Heat-Shrink Tubing Market published by Stratview Research covers in depth details associated with the Heat-Shrink Tubing Market.

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The Heat-Shrink Tubing Market is likely to witness a CAGR of 8.8% during the forecast period. The prime factors that are driving the Heat-Shrink Tubing Market is its superior thermal conductivity property leading to its wide usage in a wide array of industries.

Key Players

The following are the key players in the Heat-Shrink Tubing Market:

TE Connectivity

3M

Sumitomo Electric

ABB

HellermannTyton

Alpha Wire

Woer

Qualtek

Panduit

Zeus

Guanghai Materials

Thermosleeve

Insultab

Dasheng Heat Shrinkable Material

Changchun Heat Shrinkable Materials.

Growth drivers and Market Value:

This report, from Stratview Research, studies the Heat-Shrink Tubing Market value and growth drivers over the trend period of 2022-27. According to the report -

Heat-Shrink Tubing Market is likely to witness an impressive CAGR of 5.8% during the forecast period. Various government drives to upgrade and expand the T&D systems and incessant developments in the global power generation capacity are the major factors expected to bolster the market during the forecast period.

Segment Analysis:

Based on Material Type:

Based on the material type, the market is segmented as polyolefin, polytetrafluoroethylene, fluorinated ethylene propylene, perfluoroalkoxy alkane, ethylene tetrafluoroethylene, and others. The polyolefin segment is estimated to hold the major share of the market during the forecast period as it generates more revenue than other materials. Polyolefins are impenetrable to flame and abrasion, and are highly flexible, and have great chemical, and electrical properties.

Based on Region:

In terms of regions, Asia-Pacific is estimated to lead the heat-shrink tubing market during the forecast period, owing to plans for electrification and increasing grid investment in countries, such as Vietnam, Indonesia, and the Philippines. The markets of India and China majorly attribute for the growth in electric grid investment and developing reliance on renewable sources of power generation, which are driving the growth of the market.

Critical Questions Answered in the Report

What are the key trends in the Heat-Shrink Tubing Market?

How the market (and its various sub-segments) has grown in the last five years and what would be the growth rate in the next five years?

What is the impact of COVID-19 on Heat-Shrink Tubing Market?

What are the key strategies adopted by the major vendors to lead in the Heat-Shrink Tubing Market?

What is the market share of the top vendors?

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Stratview Research is a global market research and consulting service provider, offering syndicated and custom research reports along with growth consulting services. Our business intelligence and industry research reports offer clients with insightful and actionable market data to aid strategic decision making. These exclusive reports are the result of exclusive research methodology and are available for key industries such as chemicals, composites, advanced materials, technology, renewable energy, and more. Stratview Research helps its user’s tract the ever-evolving market scenarios through its top-notch market reports.

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Fluoropolymer Films Market To Register Unbelievable Growth By 2030

The global fluoropolymer films market is likely to expand at a significant CAGR during the forecast period (2021-2030) owing to the growing electrical and electronics industry globally, asserts market Research Future (MRFR). Fluoropolymer films are made of complex base materials offering weather resistance, high chemical resistance, optical properties, low coefficient of friction, dielectric properties, and others. Such properties make it suitable for several end-use industries like aerospace, construction, pharmaceutical, electrical & electronics, automotive, and renewable energy.

Fluoropolymer Films Market is expected to surpass the market value of over USD 3.3 billion by the year 2028 while registering a CAGR of 5.1% during the forecast 2021-2030.

Drivers and Growth Factors Impacting the Market

Fluoropolymer is extensively used in fuel tubes for vehicles, wires, and cables, mold release for microphones, semiconductor tube parts, roofing material, solar cells, photovoltaic module, cap liner, and others. With the rapidly increasing electrical and electronic industry worldwide, the global market for fluoropolymer is likely to expand during the forecast period. Increasing demand for personal devices like smartphones, television, smartwatches, wearable devices, and home appliances is predicted to foster the market growth over the assessment period. Moreover, growing investment in commercial and residential construction activities in the developing economies along with improving living standard of the consumers is propelling the market growth over the years.

On the flip side, industry participants have innovated high-cost technologies which comprise complex manufacturing process. Owing to high cost of raw material, the market is expected to lag behind during the forecast period.

Global Fluoropolymer Films Market: Segmental Analysis

The fluoropolymer market has been segmented on the basis of application, type, and region.

By mode of type, the global fluoropolymer market has been segmented into ethylene tetrafluoroethylene (ETFE), polychlorotrifluoroethylene (PCTFE), perfluoroalkoxy alkane (PFA), fluorinated ethylene propylene (FEP), polyvinylidene difluoride (PVDF), polytetrafluoroethylene (PTFE), and others. Among these, the PTFE segment holds the highest share in the market and is predicted to maintain its dominance during the assessment period due to their application in electrical and electronics, chemical processing, and other end-user industries.

By mode of application, the market has been segmented into renewable energy, pharmaceuticals, automobile, aerospace, electrical & electronics, packaging & specialty films, construction, and others. Among these, the construction segment holds a significant share and is anticipated to maintain its dominance over the forecast period. Fluorine-based organic polymer films are extensively used in construction applications like anti-graffiti coverings, water-repellent architectural fabrics, protection against extreme corrosion, cracking, fading, and others. The product is high in demand due to its characteristics such as weatherability, flame retardancy, thermal stability, etc.

Regional Insights

Asia Pacific region accounts for the largest share and is anticipated to showcase a significant growth rate during the assessment period. With the increasing industries in the developing countries like Thailand, India, and China along with growing demand for smartphones, home appliances, and laptops, the market is likely to propel in this region. Moreover, increasing production of automobiles in China is fostering the product demand.

North America is a prominent region owing to the surging demand for miniaturized electronics like wireless speakers, smartphones, and others. Moreover, the reviving automotive industry along with growing production of lightweight and fuel-efficient vehicles are likely to propel the market growth.

Europe is predicted to showcase a significant growth rate owing to the surging demand from end-use industries such as electrical & electronics, construction industry, aerospace, automotive, and others.

Competitive Analysis

The major players operating the global market are Polyfon Technology Ltd. (U.K.), Textiles Coated International (U.S.), 3M (U.S.), DUNMORE Corporation (U.S.), DowDuPont (U.S.), Honeywell International Inc (U.S.), Chemours Company (U.S.), Evonik Industries (Germany), Saint-Gobain S.A. (France), J.V. Corporation (India), Guarniflon S.p.A. (Italy), Daikin Industries Ltd. (Japan), CHUKOH CHEMICALS INDUSTRIES LTD. (Japan), ASAHI GLASS CO. LTD. (Japan), NITTO DENKO CORPORATION (Japan), and others.

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Industry News

A nanostructured gate dielectric is the most significant obstacle to expanding the use of organic semiconductors for thin-film transistors. Composed of a fluoropolymer layer followed by a nanolaminate made from two metal oxide materials, the structure serves as gate dielectric and protects the organic semiconductor which was previously vulnerable to damage from the ambient environment, even underwater.

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Fluoropolymer Tubing Market overview by recent opportunities, growth size, regional analysis and forecasts to 2031 | Arkema SA, Asahi Glass Company Limited, The Chemours Company

Global Fluoropolymer Tubing Market report from Global Insight Services is the single authoritative source of intelligence on Fluoropolymer Tubing Market. The report will provide you with analysis of impact of latest market disruptions such as Russia-Ukraine war and Covid-19 on the market. Report provides qualitative analysis of the market using various frameworks such as Porters’ and PESTLE analysis. Report includes in-depth segmentation and market size data by categories, product types, applications, and geographies. Report also includes comprehensive analysis of key issues, trends and drivers, restraints and challenges, competitive landscape, as well as recent events such as M&A activities in the market.

Fluoropolymer tubing is a type of tubing that is made from a fluoropolymer. Fluoropolymers are a type of polymer that contains fluorine atoms. They are known for their resistance to chemicals and heat. Fluoropolymer tubing is used in a variety of applications where resistance to chemicals and heat is important.

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Key Trends

Fluoropolymer tubing technology is constantly evolving in order to meet the needs of industries that rely on this type of tubing. Some of the key trends that have emerged in recent years include the following:

1. Increased use of fluoropolymer tubing in the medical industry: Fluoropolymer tubing is often used in medical applications due to its non-reactive and biocompatible properties. This type of tubing is often used for catheters, tubing for dialysis machines, and other medical devices.

2. Improved manufacturing methods: Newer manufacturing methods have led to improved quality control and higher production yields of fluoropolymer tubing. This has helped to lower the cost of this type of tubing, making it more accessible to a wider range of industries.

Key Drivers

The growing demand from the end-use industries is driving the growth of the fluoropolymer tubing market. The end-use industries are increasingly using fluoropolymer tubing due to its superior properties such as chemical resistance, high temperature resistance, and non-stick properties. The fluoropolymer tubing market is also being driven by the increasing applications of fluoropolymer tubing. Fluoropolymer tubing is used in a variety of applications such as chemical processing, oil and gas, pharmaceuticals, and food and beverage.

Market Segments

By Product Type

Polytetrafluoroethylene (PTFE)

Fluorinated ethylene-propylene (FEP)

By Application

Film

Tube

By End Use Industry

Transportation Equipment

Electrical and Electronics

By Region

North AmericaThe U.S.

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Key Players

Arkema SA

Asahi Glass Company Limited

The Chemours Company

Daikin Industries

Dongue Group

Dupont

Honeywell

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The Heat Shrink Tube Market to scale through innovations at a CAGR of 5.7% between 2022-2032

An exclusive report by Persistence Market Research observes that the heat shrink tubing market is expected to grow at a CAGR of 5.7% from an estimated US$ 237.1 million in 2021 to US$ 394.20 million by 2030. Government attempts to develop and update T&D systems, as well as ongoing increases in global power generating capacity, are projected to fuel the heat shrink tubing market.

Even though demand for Polytetrafluoroethylene (PTFE) and Fluorinated Ethylene Propylene (FEP) in the heat shrink tubing market is increasing, Polyethylene Terephthalate (PET) is likely to remain the preferred material for manufacturing due to its superior mechanical properties, including high-temperature resistance capacity and resistance to UV light, chemicals, and solvents.

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Polyethylene Terephthalate (PET) accounted for one-third of the revenue share of the heat shrink tubing market, and its rising acceptance in the electrical & electronics sector, owing to its high dielectric strength, would support its sales in the heat shrink tubing market. The ever-expanding spectrum of applications for PET heat shrink tubes is likely to drive heat shrink tubing market expansion, opening up new sales possibilities for producers.

In the future years, the use of heat shrinks tubes in the electrical and IT & telecom sectors is likely to skyrocket. Massive improvements are being pioneered in this industry to improve telecommunications and data centre security.

Heat shrink tubing may be used to dress cable assemblies, offering IT and telecom professionals more options for routing and managing complicated wire networks. The industry is predicted to continue to be driven by an increase in demand for sealing and insulation for wire protection in telecommunication connections.

In the North American market, rising industrial automation and expansion in the automotive industry are fueling the growth of the heat shrink tubing market. Furthermore, rising investment and development for improved energy transmission and distribution networks in the Middle East and Africa, as well as Latin America, is fueling the expansion of the heat shrink tubing market.

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The Asia Pacific accounted for about half of the revenue share of the heat shrink tubing market, with most developing manufacturers and major heat shrink tubing market players in the area significantly relying on the requirement for heat shrink tubes to preserve obsolete and ageing electrical infrastructure.

China dominates the Asia Pacific heat shrink tubing market due to its huge population and expanding number of electric vehicles. Development in power generating harnessing capacity for low voltage is also boosting heat shrink tubing market growth. However, China has a large number of heat shrink tubing producers in the region, which contributes to the country’s growth.

The need for heat shrink tubing kits in this region is driven not just by increased protection and insulation but also by strain relief and environmental sealing. The increased need for heat shrink tubing is likely to be exacerbated in the Asia Pacific, where power consumption is increasing due to the region’s rising economy.

Technological advancements are accelerating the adoption of insulating materials for enhanced cable wire protection in high voltage electrical infrastructure, offering growth prospects for the heat shrink tubing market. In the Asia Pacific, advances in the thick wall, flame retardant, low voltage, and halogen-free heat shrink tubing solutions are driving the heat shrink tubing market.

In the heat shrink tubing market, developed economies such as the North American market continue to face a torrent of regulatory enforcement mandates. The Nuclear Regulatory Commission has issued strict guidelines for the correct use of heat shrink tubes in nuclear power reactor plants. Heat shrink tubes installed incorrectly above electric splices and terminations may constitute a nuclear radiation danger.

Strict adherence to such requirements may dissuade important heat shrink tubing market participants from making large investments in heat shrink tubing, particularly in the nuclear power industry.

Substitute goods are being put into the heat shrink tubing market, and growing awareness about the need to decrease the use of plastic in everyday life is anticipated to stymie the growth of the heat shrink tubing market.

Since the cold shrink tubing market competes with the heat shrink tubing industry, its expansion may be hampered. Cold shrink tubing is more UV resistant than hot shrink tubing, giving it a more desirable option in several industrial areas. To install components in cold shrink tubing, no hot work or direct flame is necessary.

Hot work permits and severe rules are not necessary, and cold shrink tubing is assumed to be reliable owing to less difficult processes. These results in significant time and cost savings, making it a preferable option for important manufacturers, limiting the growth of the heat shrink tubing market.

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KEY TAKEAWAYS:

The manufacturing sector of the heat shrink tubing market’s end user sector is expected to grow at a CAGR of 6.4% during the forecast period.

The heat shrink tubing market’s top region is expected to grow at a CAGR of 6.1% during the forecast period.

China is expected to reach a heat shrink tubing market size of US$ 27.3 Million by 2032, with a CAGR of 6.5% over the analysed period.

The US is expected to reach a heat shrink tubing market size of US$ 121.2 Million by 2032, with a CAGR of 6.2% over the analysed period.

The UK is expected to reach a heat shrink tubing market size of US$ 11.8 Million by 2032, with a CAGR of 6.3% over the research period.

Japan is expected to reach a heat shrink tubing market size of US$ 23.5 Million by 2032, with a CAGR of 6.3% over the research period.

COMPETITIVE LANDSCAPE:

The major players in the heat-shrink tubing market are TE CONNECTIVITY, SUMITOMO ELECTRIC INDUSTRIES, LTD., PRYSMIAN GROUP, ABB Ltd, and 3M.

TE Connectivity released BATTU heat-shrink tubing in March 2019, a dual-wall; fire-retardant solution designed for battery/power cable to terminal applications in industrial and commercial vehicles, construction equipment, and generators sets. With a 2:1 shrink ratio, BATTU tubing products operate very well in tough conditions.

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Plastic Injection Molding for Medical Devices

Injection molding is the plastic parts manufacturing method. By injecting molten plastic material in the molds you can create large volume-based plastic parts effortlessly.

Medical device manufacturers are now taking the help of plastic injection molding to produce durable, more efficient, and versatile products. This plastic parts manufacturing process is used to create medial products such as-

Surgical instruments.

Dental implants.

Tubes.

Prosthetics.

Insert-molded styles and biopsy sets.

Importance of plastic Injection Mold Manufacturing in the Medical Industry.

Medical device products come in various shapes, sizes, and designs. Sometimes it is very difficult for the manufacturer to create accurate medical products. Only plastic injection mold can handle this task. Like surgical devices must be light weight and designed with great accuracy. Devices like needles, tubing, connectors, and bags are designed for drug delivery must be durable, transparent, and chemically inert. In short, plastic injection molding is suitable for manufacturing medical devices.

Our high-skill professionals are the best match for meeting the low-cost and high-quality tooling requirements at your organization through cheap injection molding.You can buy the moulds directly from us at factory prices.

Picking Medical- Grade Material.

Like any other manufacturing process, choosing the right material to manufacture the products is crucial. Because the quality of the products depends on the material, we choose.

The following are the common material that can meet with the demand of the medical industry-

Polytetrafluoroethylene: This plastic material is also known as Teflon. It is resistant to heat and harsh weather conditions and uses pipes to handle corrosive chemicals because of non-corrosion properties.

Perfluoroalkoxy: This material is commonly used for manufacturing laboratory instruments. It is flexible, optically transparent, and chemical inertness.

Fluorinated ethylene propylene: This material is used to produce medical devices that are subjected to weathering like sunlight. It is commonly used in manufacturing containers, packaging films, and breather patches.

Propylene: It is thermoplastic used to manufacture the products that can degrade under the sunlight and remain stable without losing the functionality.

Polycarbonate: It is a versatile material that can withstand heat and cold. The temperature stability of this material makes it ideal to manufacture blood filter housing, centrifugal force separators and syringes.

Should you consider a plastic injection molding manufacturing process for your next medical project?

Compared to other materials, plastic offers many remarkable advantages when it comes to manufacturing medical devices. Many medical devices are difficult to manufacture due to their complex designs and functionality. The plastic injection mould manufacturer process can create easily. If you manufacture the medical devices by using the right material, it offers you strength, heat stability, high resistance to weathering at an affordable cost.

Final Say:

Needless to say, the plastic injection mold process is suitable for manufacturing medical products with intricate details at a low cost. If you seek the renowned and reputed plastic injection molding Belgium that has produced more than 110 billion plastic parts, feel free to contact us. Our experienced engineers can create a prototype of the product that meets your demands and budget. We offer you the medical products that made with transparent material, high resistance to heat, and chemically inert.

Shell & Tube Heat Exchanger Market - Forecast(2022 - 2027)

Shell & Tube Heat Exchanger Market is forecast to reach $7.4 billion by 2025, after growing at a CAGR of 4.1% during 2020-2025. Owing to their easy maintenance, robust geometry design, and potential upgrades, shell and tube heat exchanger penetration is witnessing significant growth in oil refineries and petrochemical plants. Also, heat exchangers for shells and tubes are expected to gain popularity in the future due to their improved resistance to high-temperature applications and the ability to deliver protection against fouling. Hence, due to the rising demand for modern, new equipment in the petrochemical, pharmaceutical and power generation industries, providing high efficiency and resistance to corrosion is expected to raise the shell & tube heat exchanger industry in the forecast period.

Report Coverage

The: “Shell & Tube Heat Exchanger Market Report – Forecast (2020-2025)”, by IndustryARC, covers an in-depth analysis of the following segments of the shell & tube heat exchanger market.

By Material Type: Steel, Hastelloy, Titanium, Nickel & Nickel Alloys, Tantalum, and Others.

By End Use: Power Generation, Petrochemical Industry, Chemical Industry, Food & Beverage Industry, HVAC & Refrigeration, Pulp & Paper Industry, and Others.

By Geography: North America, South America, Asia Pacific, Europe, and Middle East & Africa.

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Key Takeaways

Europe dominated the market share of shell & tube heat exchangers in the area due to the large-scale demand of shell & tube heat exchangers for chemicals industry in this region.

Due to the continuous use of shell & tube heat exchangers for the production of various chemicals such as fertilizers and specialty chemicals worldwide, in the chemicals industry is predicted to expand dramatically over the projected era.

Furthermore, the rise in demand for fertilizers, fibers, industrial gasses and other inorganic and organic chemicals, which will increase the demand for the manufacture of appliances, such as heat exchangers, boilers and chillers, would boost market growth in the coming years.

Also, due to the high resistance to extreme temperatures, fluoropolymers such as perfluoro alkoxy alkane (PFA) and fluorinated ethylene propylene (FEP) are used to produce the tubing material in the shell & tube heat exchanger market.

Due to COVID-19 palindrome and nationwide lockdown there is a pause in the manufacturing industry due to the shortage of the supply of raw materials for the production of shell & tube heat exchangers. Thus, it is anticipated to hinder the growth of the market in the forecast period.

Shell & Tube Heat Exchanger Market Segment Analysis - By Material Type

Steel is extensively used in the shell & tube heat exchanger market. Stainless steels are iron-based alloys with a minimum chromium content of 10.5 per cent. The amount of stainless steel used for heat exchanger systems is that the industry wants to make its processes more effective and lower expensive shutdowns and to increase commodity performance. The properties of steel including corrosion resistance in chemical environments and cooling waters, high temperature resistance to scaling and oxidation, strong strength in low and high temperature applications, and corrosion-related fouling resistance are expected to improve material penetration in heat exchangers. Thus, the rising demand for steel in the shell & tube heat exchanger will drive the market growth in the forecast period.

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Shell & Tube Heat Exchanger Market Segment Analysis - By End Use

Chemical industry held the largest share in the shell & tube heat exchanger market in 2019 and is projected to grow at a CAGR of 3.9% during the forecast period 2020-2025. Due to their features including simple servicing and restoration, compact construction and high-pressure operations, and the improved penetration of the shell and tube heat exchanger the market demand will rise. The heat exchangers used in the chemical industry are primarily made of corrosion-resistant materials, including zirconium, titanium, nickel alloys, stainless steel duplex and stainless steel austenitic. The chemical industry is rising at a significant rate as investments in the research and development of new chemicals such as specialty chemicals and fine chemicals are increasing. These chemicals require heat exchange equipment which fuels the demand for shells & tubes heat exchangers. Increasing demand for petrochemicals, fibers, industrial gasses, fertilizers, chlorine-alkali, and other organic and inorganic chemicals, has also led to an increased demand for production equipment such as boilers, chillers, heat exchangers, etc. worldwide. All these factors are likely to fuel the demand for shells and tubes heat exchanger market in the forecast period.

Shell & Tube Heat Exchanger Market Segment Analysis - Geography

Europe held the largest share with 32.3% in the shell & tube heat exchanger market. This growth is due to increased product penetration in various end-use industries, including power generation, petrochemicals, plastics, HVAC, and refrigeration, as well as food and beverages. Due to the rapidly increasing industrial infrastructure attracting many global players in the chemical industry, government initiatives in developing countries such as the United Kingdom and Germany have attracted strong growth from the chemical industry. The chemical industry is Germany's largest manufacturing sector and serves both domestic and export needs. The heat exchangers for shells and tubes are used in the manufacture of chemical products in industrial chemical production. Germany led the way for shell & tube heat exchangers in the last 2–3 years due to the growing way for chemicals. The European Council of Chemical Industry expects the European Union chemical production to decrease by 1 per cent in 2019 relative to 2018, according to Cefic Facts & Figures. For the year 2020, chemical production is expected to stay on the same level as 2019. Due to COVID-19 palindrome and nationwide lockdown, the overall Europe chemical production was slightly negative in the first half of 2019.

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Shell & Tube Heat Exchanger Market Drivers

Rapidly growing demand of shell & tube heat exchanger from pulp & paperCompared with the refining industry, the pulp & paper manufacturing industry uses large amounts of heat in their processes, typically in the mid and low temperature range. The pulp and paper industries use a great deal of energy in their different drying processes. The drying process is important and as a result, the air heat exchanger shell & tube must be durable and also highly successful in order to reduce the energy bills of the facility. Pressurized water reactor uses steam generator, a U-tube heat exchanger, to transform the reactor vessel's thermal conductivity into vapor. By reusing waste heat, the paper industry can still make savings on its energy consumption. However, most industrial waste heat temperature is however too low to be reused. The industrial pulp & paper process is consequently very energy-intensive. This industry aims for heat pumps to lift the temperature to greater levels. Thus, use of shell & tube heat exchanger for various applications in pulp & paper industry will drive the market in the forecast period.

Increasing use of shell & tube heat exchanger in the food and beverage industryShell & Tube heat exchangers help optimize production, maximize raw materials and reduce energy consumption, waste and emissions. Shell & Tube heat exchangers treat very delicate and viscous products that are capable of pumping at high pressure without destroying food particles. In the food and beverage industry, it is used at ideal temperatures in ovens, cookers, food processing & preheating, milk pasteurization, beer cooling and pasteurization, refrigeration or chilling of the final product. Also, shell & tube heat exchangers make products safe for consumption and extend shelf life by preventing growth of harmful microbes. Thus, the increasing use of shell & tube heat exchanger in food & beverage sector will drive the market in the projected period.

Shell & Tube Heat Exchanger Market Challenges

Maintenance difficulties in shell & tube heat exchanger Cleaning and maintenance are problematic, as a tube cooler requires sufficient leeway to one side to expel the tube nest. An exchange of shells and tubes consists of a number of tubes mounted inside a cylindrical shell Is difficult to clean. Failure to keep all tubes clean may result in flow termination in time, which may result in leaks and ruptures in the tubes. For major changes in pressures and/or thermal efficiency, exchangers prone to fouling should be controlled. While heat exchanger fouling may result from a variety of mechanisms, it is usually one that predominates over time, and increases. The tube surfaces are returned to a nearly bare metal state each time the tube deposits, sedimentation, biofouling, and obstructions are removed. This restarts the heat exchanger's lifecycle as the protective oxides reconstruct themselves quickly to create a passive cleaned tube.

Market Landscape

Technology launches, acquisitions, and R&D activities are key strategies adopted by players in shell & tube heat exchanger market. In 2019, the market of shell & tube heat exchanger has been consolidated by the top five players accounting for xx% of the share. Major players in the shell & tube heat exchanger market are Kelvion Holdings GmbH, Alfa Laval AB, HRS Heat Exchangers, Brask Inc., Koch Heat Transfer Company, Thermax Limited, SPX Corporation, API Heat Transfer Inc., and Southern Heat Exchanger Corporation among others.

Acquisitions/Technology Launches

In May 2019, Alfa Laval established a manufacturing plant for the production of brazed plate heat exchangers in the USA. This manufacturing plant will cater for North America's increasing demand for heat exchangers. It also provides rapid response time and reduced lead times for its US customer base, which will help the company increase its revenues from the North America region.

In January 2019, Kelvion Holdings GmbH, launched exhausts gas heat exchangers, compact and ideal for industrial installations and power stations.

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Why choose EPDM elbow

The ball material of the rubber elbow has different materials according to the different media, such as EPDM, natural rubber, fluorine rubber, nitrile rubber and so on. As the EPDM elbow wholesaler, we want to share reasons for choosing EPDM elbow.

Rubber ball material

The rubber elbow sphere is composed of an inner rubber layer, a reinforced layer with a multi-layer scraped nylon cord fabric, and an outer rubber layer composite rubber tube. According to different materials, they have acid, alkali, heat resistance, wear resistance, and corrosion resistance. , Oil resistance and other functions.

15kV 200A Elbow connector

Why EPDM elbow

EPDM is a copolymer of ethylene, propylene and a small amount of non-conjugated diene. It is a type of ethylene-propylene rubber. The main chain is composed of chemically stable saturated hydrocarbons. It only contains unsaturated double bonds in the side chain, so it has many advantages, such as ozone resistance, weather resistance, heat resistance and other aging resistance.

EPDM elbow features

Small size, light weight, fine flexibility, easy installation and maintenance.

It can produce lateral, axial, and angular displacement during installation, and is not restricted by pipes that are not through core and flanges are not parallel.

It can reduce the transmission noise of the structure while working, and has a strong vibration absorption capacity.

Wide application

In addition to being applied to elbow, they can also be widely used in automotive parts, automotive seals, waterproof materials for construction, heat-resistant hoses, adhesive tapes, wire and cable sheaths and other fields. For example, a material suitable for outdoor venues, suitable for kindergartens, parks, community playgrounds, trails and other places, is comfortable and elastic, and is also non-slip, wear-resistant, long life, low-density and high-filling. The price volatility is relatively large and varies from region to region.

EPDM elbow installation precautions

When installing the rubber elbow, it is strictly forbidden to install it beyond the displacement limit. The installation bolts should be symmetrical and tightened gradually to prevent local leakage.

For working pressures above 1.6MPa, the installation bolts must have elastic pressure pads to prevent the bolts from loosening during work.

During vertical installation, both ends of the joint pipe should be supported by vertical forces, and anti-pull-off devices may be adopted to prevent the work from being pulled off under pressure. The installation part of the rubber elbow should be far away from the heat source and ozone area. It is strictly forbidden to expose to strong radiation light and use the medium that does not meet the requirements of this product.

It is strictly forbidden for the rubber elbow to scratch the surface and sealing surface with sharp instruments during transportation and handling.

Connection method: Flange connection.

Advantages of using 90 degree EPDW rubber elbow for drainage pipe

The 90-degree rubber elbow has a reasonable structure, strong vibration absorption capacity, good vibration and noise reduction effect, can withstand higher working pressure, and can play a good role in displacement compensation for compression, tension, and torsion. In a pipeline system with a relatively small space, when some pump room pipelines encounter an underground pump room during installation, the space is very limited, and it is impossible to install a single ball type rubber soft joint 90 degree rubber elbow like a normal pipeline. Right-angle rubber soft joints can be installed.

If you are looking for EPDW elbow wholesalers to ask for good suggestions for your target objects, welcome to contact us to provide you with solutions.

Fluoropolymers Industry | Size, Share, Trends, Demand, Key Player profile and Regional Outlook by 2027

Competitive Landscape

Fluoropolymers have seen increased demand over the years, due to bio-based fluoropolymers to end-users and increased demand for architectural coating. Companies functioning in the global market are also being challenged due to strict rules and regulations and unfavorable policies. Mergers and acquisitions by fluoropolymers market companies are anticipated to help the market during the forecast period 2015-2023. As the fluoropolymers market is set to register a high CAGR of 6.50% and is also anticipated to reach a US$11,823.1 million by 2027, the report highlights key areas companies need to focus on. The report suggests that the market will see a healthy growth in the long run till 2023. Based on SWOT analysis and fluoropolymers market’s analysis based on Porters’ Five Force Model presented in the market report. Mergers and acquisitions by fluoropolymers market companies are anticipated to haelp the market during the forecast period 2015-2023.

Industry News

The Italian maker of fluoropolymer composites, Heroflon S.p.A. was recently acquired by Daikin Industries, Ltd. After completing the relevant proceedings, Daikin will acquire all company shares held by Heroflon Executive Officers at the end of October 2017. Heroflon is a producer of compounds that manufactures fluoropolymers that combine different materials with high efficiency. Its product line consists of fluoropolymer compounds and polytetrafluoroethylene-centric micropowder. PTFE is a fluoropolymer that is highly operational in various sectors including the automobile, building, electrical and chemical industries.

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The global fluoropolymers market, during the forecast period 2015-2023, will register growth at a CAGR of 6.50%. The market for fluoropolymers is set to reach US$11,823.1 million by 2027. As per fluoropolymers market analysts, the global market is anticipated to witness growth owing to the factors such as ongoing R&D for product development as well as various end-use and high-tech applications. However, the global market will face challenges and restraints due to stringent regulations by governments and trend towards the alternative use of fluoropolymers during the forecast period 2015-2023.

The escalating demand from automotive and building & construction industries in the fluoropolymers market is set to play a key role in determining the growth potential during 2015-2023years. Analysts have also studied the report market to understand potential threats and challenges the fluoropolymers market companies could face. Although the market report is poised to grow at a fast pace across application, end-use industry, region, and type segments, factors such as the availability of alternatives could slow down the report market's growth worldwide.

Market Segmentation

The fluoropolymers market has been segmented into application, end-use industry, region, and type. Based on the segment which is application, the market is categorized on the basis of additives, coatings, films and sheets, tubes, and others. The global market for fluoropolymers is further segmented based on the end-use industry into automotive, building and construction, chemical processing, electrical and electronics, household, industrial equipment, medical, and others. Furthermore, the market, on the basis of type is segmented into Ethylene Tetrafluoroethylene (ETFE), Fluorinated Ethylene-Propylene (FEP), Fluoroelastomers (FKM), Polychlorotrifluoroethylene (PCTFE), Polytetrafluoroethylene (PTFE), Polyvinylidene Fluoride (PVDF), and others.

The global market research report covers all the aspects of the fluoropolymers market based on the segmental analysis of these application, end-use industry, region, and type segments. Analysts have also studied the global fluoropolymers market's regional markets spread across many continents and countries. The application, end-use industry, region, and type segments along with their sub-segments have been analyzed and companies functioning in the market across these segments are profiled and analyzed based on input and feedback from fluoropolymers market based decision makers as well as primary and secondary sources. The research report presents analysis based information for companies functioning in the market.

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Regional Overview

Consumers looking for alternative product solutions may hinder the fluoropolymers market growth. The market research report suggests that companies in the market could be supported by the increasing shift towards green fluoropolymers as well as manufacturers extending their product portfolios during the forecast period. The fluoropolymers market is set to register growth at a high CAGR owing to these key factors. The market report is spread across North America, Europe, Asia-Pacific, and other parts of the world. The global market research report reveals that APAC, North America, and Europe regional fluoropolymers markets will dominate the global market for fluoropolymers during the forecast period 2015-2023. As per market analysts, the market is set to witness tremendous growth across coatings and chemical processing segments in North America which covers research markets across the United States, Canada, Mexico and several other regional markets. Companies active in the market are also analyzed and studied in the fluoropolymers market research report.

Europe covers smaller market segments of Germany, Italy, France, and the United Kingdom. Additionally, the fluoropolymers market research report covers the Asia-Pacific region covering fluoropolymers markets from India, China, Japan, Australia, and others. The market is also spread across the rest of the world. The market report covers all such regions including the Middle East, Africa, Brazil, and others.

Shrink Hood TubesAnalysis, Historic Data and Forecast 2021-2028

The Shrink Hood Tubes market report provides a detailed analysis of global market size, regional and country-level market size, segmentation market growth, market share, competitive Landscape, sales analysis, impact of domestic and global market players, value chain optimization, trade regulations, recent developments, opportunities analysis, strategic market growth analysis, product launches, area marketplace expanding, and technological innovations.

ALSO READ : http://www.marketwatch.com/story/shrink-hood-tubes-market-research-report-with-size-share-value-cagr-outlook-analysis-latest-updates-data-and-news-2021-2026-2021-06-23

Market segmentation Shrink Hood Tubes market is split by Type and by Application. For the period 2016-2026, the growth among segments provide accurate calculations and forecasts for revenue by Type and by Application. This analysis can help you expand your business by targeting qualified niche markets.

ALSO READ : http://www.marketwatch.com/story/june-2021-report-on-global-licorice-extract-cas-68916-91-6-market-overview-size-share-and-trends-2021-2026-2021-06-03

Market segment by Type, covers Polyolefin Polytetrafluoroethylene Fluorinated Ethylene Propylene Others

ALSO READ : http://www.marketwatch.com/story/june-2021-report-on-global-exhaust-aftertreatment-systems-market-overview-size-share-and-trends-2021-2026-2021-06-08

Market segment by Application, can be divided into Utilities Chemical Automotive Food and Beverage Others (healthcare, aerospace, military industry)

ALSO READ : http://www.marketwatch.com/story/june-2021-report-on-global-it-outsourcing-market-overview-size-share-and-trends-2021-2026-2021-06-09

Market segment by players, this report covers Coveris TE Connectivity The 3M Company Sumitomo Electric Industries, Ltd. ABB Group HellermannTyton Alpha Wire Company Shenzhen Woer Heat - Shrinkable Material Co., Ltd. Qualtek Electronics Corporation Panduit Zeus Huizhou Guanghai Electronic Insulation Materials Co.,Ltd. Thermosleeve USA Insultab Dasheng Heat Shrinkable Material Changchun Heat Shrinkable Materials

Market segment by regions, regional analysis covers North America (United States, Canada, and Mexico) Europe (Germany, France, UK, Russia, Italy, and Rest of Europe) Asia-Pacific (China, Japan, South Korea, India, Southeast Asia, Australia, and Rest of Asia-Pacific) South America (Brazil, Argentina, Rest of South America) Middle East & Africa (Turkey, Saudi Arabia, UAE, Rest of Middle East & Africa)

The content of the study subjects, includes a total of 12 chapters: Chapter 1, to describe Shrink Hood Tubes product scope, market overview, market opportunities, market driving force and market risks. Chapter 2, to profile the top players of Shrink Hood Tubes, with revenue, gross margin and global market share of Shrink Hood Tubes from 2019 to 2021. Chapter 3, the Shrink Hood Tubes competitive situation, revenue and global market share of top players are analyzed emphatically by landscape contrast. Chapter 4 and 5, to segment the market size by type and application, with revenue and growth rate by type, application, from 2016 to 2026. Chapter 6, 7, 8, 9, and 10, to break the market size data at the country level, with revenue and market share for key countries in the world, from 2016 to 2021.and Shrink Hood Tubes market forecast, by regions, type and application, with revenue, from 2021 to 2026. Chapter 11 and 12, to describe Shrink Hood Tubes research findings and conclusion, appendix and data source.

Table of Contents

1 Market Overview 1.1 Product Overview and Scope of Shrink Hood Tubes 1.2 Classification of Shrink Hood Tubes by Type 1.2.1 Overview: Global Shrink Hood Tubes Market Size by Type: 2020 Versus 2021 Versus 2026 1.2.2 Global Shrink Hood Tubes Revenue Market Share by Type in 2020 1.2.3 Polyolefin 1.2.4 Polytetrafluoroethylene 1.2.5 Fluorinated Ethylene Propylene 1.2.6 Others 1.3 Global Shrink Hood Tubes Market by Application 1.3.1 Overview: Global Shrink Hood Tubes Market Size by Application: 2020 Versus 2021 Versus 2026 1.3.2 Utilities 1.3.3 Chemical 1.3.4 Automotive 1.3.5 Food and Beverage 1.3.6 Others (healthcare, aerospace, military industry) 1.4 Global Shrink Hood Tubes Market Size & Forecast 1.5 Global Shrink Hood Tubes Market Size and Forecast by Region 1.5.1 Global Shrink Hood Tubes Market Size by Region: 2016 VS 2021 VS 2026 1.5.2 Global Shrink Hood Tubes Market Size by Region, (2016-2021) 1.5.3 North America Shrink Hood Tubes Market Size and Prospect (2016-2026) 1.5.4 Europe Shrink Hood Tubes Market Size and Prospect (2016-2026) 1.5.5 Asia-Pacific Shrink Hood Tubes Market Size and Prospect (2016-2026) 1.5.6 South America Shrink Hood Tubes Market Size and Prospect (2016-2026) 1.5.7 Middle East and Africa Shrink Hood Tubes Market Size and Prospect (2016-2026) 1.6 Market Drivers, Restraints and Trends ALSO READ : http://www.marketwatch.com/story/june-2021-report-on-global-sustained-release-injectables-market-overview-size-share-and-trends-2021-2026-2021-06-10

1.6.1 Shrink Hood Tubes Market Drivers 1.6.2 Shrink Hood Tubes Market Restraints 1.6.3 Shrink Hood Tubes Trends Analysis 2 Company Profiles 2.1 Coveris 2.1.1 Coveris Details 2.1.2 Coveris Major Business 2.1.3 Coveris Shrink Hood Tubes Product and Solutions 2.1.4 Coveris Shrink Hood Tubes Revenue, Gross Margin and Market Share (2019-2021) 2.1.5 Coveris Recent Developments and Future Plans 2.2 TE Connectivity 2.2.1 TE Connectivity Details 2.2.2 TE Connectivity Major Business 2.2.3 TE Connectivity Shrink Hood Tubes Product and Solutions 2.2.4 TE Connectivity Shrink Hood Tubes Revenue, Gross Margin and Market Share (2019-2021) 2.2.5 TE Connectivity Recent Developments and Future Plans 2.3 The 3M Company

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Heat-Shrink Tubing Market Clinical Research Analysis and Global Outlook 2022 to 2027

Stratview Research delivers key insights on the global Heat-Shrink Tubing Market. According to Stratview Research, the market is estimated to grow at a decent CAGR of 5.1% during the forecast period to reach a value of US$ 310 Million in 2027.

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The present report can be of high utility for the key decision-makers and growth strategists in terms of precise market insights, forthcoming growth opportunities, and key success factors. Especially, the report also analyses and mentions the possible impact of COVID-19 on the market dynamics. This will not only help in mitigating the uncertain business environment, but also help in rearranging the strategies and future- decisions in a fruitful manner.

Key Players

The following are some of the key players in the Heat-Shrink Tubing Market:

TE Connectivity

3M

Sumitomo Electric

ABB

HellermannTyton

Alpha Wire

Woer

Qualtek

Panduit

Zeus

Guanghai Materials

Thermosleeve

Insultab

Dasheng Heat Shrinkable Material

Changchun Heat Shrinkable Materials.

Growth drivers and Market Value:

This report, from Stratview Research, studies the Heat-Shrink Tubing Market value and growth drivers over the trend period of 2022-27. According to the report -

Heat-Shrink Tubing Market is likely to witness an impressive CAGR of 5.8% during the forecast period. Various government drives to upgrade and expand the T&D systems and incessant developments in the global power generation capacity are the major factors expected to bolster the market during the forecast period.

Segment Analysis:

Based on Material Type:

Based on the material type, the market is segmented as polyolefin, polytetrafluoroethylene, fluorinated ethylene propylene, perfluoroalkoxy alkane, ethylene tetrafluoroethylene, and others. The polyolefin segment is estimated to hold the major share of the market during the forecast period as it generates more revenue than other materials. Polyolefins are impenetrable to flame and abrasion, and are highly flexible, and have great chemical, and electrical properties.

Based on Region:

In terms of regions, Asia-Pacific is estimated to lead the heat-shrink tubing market during the forecast period, owing to plans for electrification and increasing grid investment in countries, such as Vietnam, Indonesia, and the Philippines. The markets of India and China majorly attribute for the growth in electric grid investment and developing reliance on renewable sources of power generation, which are driving the growth of the market.

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FREQUENTLY ASKED QUESTIONS

The report answers several questions related to the market. The user can get to know the answers to the following questions…

What is the global demand for Heat-Shrink Tubing Market in terms of revenue?

Which are the prominent players in the market?

At what CAGR is the market projected to grow within the forecast period?

What are the driving factors fuelling the growth of the market?

Which region accounted for the largest share in the market?

How did the Covid19 impacted the market?

How long will it take to recover from the Covid impact?

Why Stratview Research?

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Polyurethane: Recent Engineering Contributions

Abstract

Polyurethane is one of the most versatile polymers which stands out with a wide range of tunable properties such as chemical stability, flexibility, abrasion and scratch resistance, toughness and biodegradability. It is a unique polymer containing alternating soft and hard segments. This review covers the most recent (2018-2019) engineering research contributions done for the synthesis, properties and applications of the polyurethane foams, coatings, adhesives, sealants, elastomers, composites and insists on the important aspects and realizations related to the polyurethane flammability and acoustic.

Keywords: Polyurethane Synthesis; Applications; Properties; Flammability; Acoustics

Abbreviations: AC: Alternative Current; BPAF: 4,4’ [2,2,2,-trifluoro-1-(trifluoromethyl)ethylidene] bisphenol; CNT: Carbon Nano tube; DAP: Dimer fatty acid band polyol; DC: Direct current; DMA: Dynamic mechanic analysis; DSC: Dynamic scanning calorimetry; DTP: N,N’,N’’-tri(dietoxy) phosphoramide; EG: Expanded graphite; EMD: Non-Reactive Phosphonate; EPUUS: Ureaurethane elastomer; FGO: Functionalized graphene oxide; FHPO-PO: Phosphorous Containing Polyether Polyol; FR: Fire Retardant; FTIR: Fourier Transform Infrared Spectroscopy; FTPU: Fluorinated Thermoplastic Polyurethane; G: Graphene; GO: Graphene oxide; HFBA 2,2,3,3,4,: heptafluoro-butiric acid 2,2-bis-hydroxymethyl-butyl ester; HRR: Heat release rate; HPU: Hyper Branched Polyurethane; LMPET: Low Melting Polyester; LOI: Limited Oxygen Index; MW: Molecular Weight; PEG: Poly(ethylene glycol); PHRR: Peak Heat Release Rate; PPG: Poly (propylene glycol); POSS Polyhedral Oligomeric Silsequioxanes; PU: Polyurethane; PU FR: Polyurethane with FR; RO: Rape seed oil; SEM: Scanning Electron Microscopy; SPB: Soybean Oil Based Polyol; TEM: Transmission Electron microscopy; TGA: Thermo gravimetry analysis; THRR: Total heat release rate; THR: Total heat release; TPIA: Acylhydrazine; TPID: Disulfide bonds; TPU: Thermoplastic polyurethane; VOCs: Volatile organic compounds

Introduction

Polyurethanes (PUs) constitute one of the most versatile class of macromolecular compounds known nowadays. They can contain a diversity of functional groups such as ether, ester, amide, urea, biuret, alophanate, uretidione, carbodiimide, isocyanurate, along with the urethane one (-NH-CO-O-) which open possibilities to react with many other components. PUs are synthesized by polycondensation reaction in which the macromolecular chain increases as the reaction progresses. This reaction can produce linear, slightly branched, or hyper branched macromolecules like in thermoplastics or they may have a crosslinked network leading to thermosetings. A recent kinetics study highlights the difficulties in quantifying the synthesis of linear PUs [1]. The main chemicals used for PU synthesis are polyols, isocyanates, and chain extenders having hydroxyl or amine group. PU contains in its macromolecules soft and hard segments; the former are made by the reaction between isocyanate and polyol, and the latter by the reaction between isocyanate and chain extender, both these components having 2 or 3 functional groups. In the PU macromolecule the polyol provides the elasticity, and the isocyanate provides the mechanical strength. Recently it has been reported new types of PUs made by the polyaddtion participation of diisocyanates. To perform the polyaddition with diols in order to obtain PU, mostly methylene diphenyl diisocyanate and hexamethylene diisocyanate were chosen [2]. A method for solving a system of bulk polyaddition of 2,4-toluene diisocyanate with 1,4-butanediol process balance equations, allowing the determination of the kinetic parameters is presented. The approach provides an opportunity to associate kinetic parameters with the average molar mass of the mixture and thus with the viscosity [3].

Beside PU as a simple polymer, it is also used in various types of composites together with other compounds. These can be molecular composites, fiber composites, and nano filled composites. Like in the case of other groups of composites the interaction matrix-filler plays an important role, for instance for PU nano composites the interface PU-nanofiller in cases of special silica, polyhedral oligomeric silsequioxanes (POSS), carbon nano tube (CNT), graphene (G), graphene oxide (GO), metallic nano particles are also very important [4]. PUs are processed to obtain various products such as flexible and rigid foams for construction and furniture items, sport equipments, coatings, adhesives, sealants, elastomers, fibers, medicine products. Adding other components beside polyols and isocyanates during the PU synthesis contributes to the improvement of some PU properties. For instance, tridecanoic acid added to toluene diisocyanate based PU is able to extend its working time with minimal changes to physical and chemical properties [5]. Another example is that of recycled polyol and benzimidazole grafted onto PU to enhance the surface hydrophilicity [6]. Due to the effects of PUs on human health, the replacement of toxic isocyanates with biocomponents is one of the main recent research direction related to PU synthesis [7]. The raw components necessary for the synthesis of PU can be obtained from natural products to substitute petroleum as their basic resource. Compared to isocyanates, the biobased raw materials possess many advantages like biodegradability, sustainability, nontoxicity and environmentally benign attributes [8]. Polyester polyols from renewable resources have gained important interest in the PU domain. Without petroleum-based polyols, castor oil polyols have been used as soft segments in PU [9]. Biobased PUs was also obtained from fatty acids with double functionality synthesized through cross-metathesis of oleic acid and oleic alcohol [10]. With azelate polyols produced from n-alkanediols with even number of CH₂ repeating units thermoplastic PUs (TPU)s result with increased hardness, tensile and tear strength [11].

From crystalline azelate polyol and amorphous azelate polyol two sets of segmented TPUs were prepared. Their study showed that the crystalline azelate polyols are suitable for dynamic applications and the amorphous ones are suggested for coatings and adhesives [12]. The product of 1-butene methatesis of canola triacylglicerol with shortened structure, terminal double bonds and oligomers was used to synthesize novel polyols and PU foams. The study highlights that one can improve and control jointly the mechanical properties and deformation recovery ability of biobased PU foams by combining primary functional group oligomers, and high molar volume molecules in the polyols [13]. Dimer fatty acid-based polyol (DAP) was used to substitute petrochemical DAP and has been used to produce rigid PU foam. The research data indicated that bio-polyol DAP can substitute partial petrochemical polyol to produce rigid PU foams with good comprehensive performance [14]. A series of PUs nonisocyanate were produced from the transurethanization between 2,5-bis(hydroxymethyl)furan and dicarbamates obtained from metoxycarbonylation of diamines with dimethyl carbonate [15]. Other example of studies using bio-components will be presented. This paper will review the most recent studies done on PU products like foams coatings, adhesives, sealants, elastomers, and composites, and on flammability and acoustic properties.

Research Contributions

Foams

During the production of PU foam using aminophosphonated polyols the thermal resistance was confirmed and a lower peak of heat release rate (PHRR) and lower smoke production was found [16]. A polyol obtained by glycolysis of waste rigid PU foams was used to produce a new rigid foam. This new foam showed higher compressive strength, thermal insulation, and self-extinguishing property compared with conventional foam [17]. Liquefied rice husk with different NCO/OH ratios was used to produce PU foams [18]. The effect of crosslinking agent on the properties and morphology of semi-rigid waterborn PU (WPU) foam was studied. The crosslinking density of the foams was adjusted by varying the amount of triethanolamine. The most characteristics processes to produce the foam are related to foaming and gelation. Increasing the amount of triethanolamine the crosslinking density increased and the swelling ratio decreased from 294.9 to 194.7%, Tg increased from -14.2 to-8.6 ⁰C [19]. To optimize the formulation of a PU foam for better sound absorption, a study was carried out with a response surface methodology to investigate the effects of different variables, catalysts and polyethylene fiber. For correlating experimental data, a mathematical model was developed, and model parameters were optimized by adoptive simulated annealing algoritm [20]. The optimization of rigid WPU foams obtained from a polyol functionalized with GO has been the object of a recent study. A series of rigid WPU foams were synthesized by varying either the isocyanate index, catalyst amounts, the surfactant contents or a combination of these three components. The obtained results show how controlling WPU formulations allows to improve important properties like mechanical and thermal of rigid WPU foams containing GO [21].

The effects of shear thickening fluid content and SiO₂ size on the cell structure, mechanical performance, acoustic absorption, and thermal performance of shear thickening fluid/PU foam were explored [22]. Adding to a flexible PU foam a negative powder modified with a silane coupling agent led to the improvement of important properties such as thermal stability, tensile strength and resilience [23]. Diferential scanning calorimetry (DSC), thermo gravimetry analysis (TGA), and Fourier transform infrared spectroscopy (FTIR) were used to measure the thermokinetics and degradation of soybean oil-based PU foam. The thermodynamic properties and thermal stability during the degradation were also studied. The degradation included 3 or 4 step-degradation profiles. As the soybean oil content or NCO/OH molar ratio increases, the thermal stability of the foam, the activation energy, and reaction rate increased [24]. A technique for the production of new cheaper components able to substitute polyols for the production of PU-polyisocyanurate foams is presented. The influence of the components on the foam flammability, thermal properties and other characteristics was examined [25].

Coatings

New biobased PU coatings with lignin were studied. A diisocyanate obtained from lignin-derived vanilic acid and crosslinked with three different nonchemically modified technical lignins namely mild acetone organosolv, kraft, and soda. The results of the research showed that the reaction of a ligninderived biobased diisocyanate represent an interesting way for the production of TPU coating. The study also showed that the reaction of lignin-derived biobased diisocyanate represents an interesting way for the production of TPU coatings with a high biomass content that can find applications as an alternative to petroleum products [26]. By using stoichiometric proportions of PU polyamines and aliphatic epoxies as crosslinker, coatings were produced. These new products possess flexibility at low temperatures and resistance to chemicals, but their thermostability is low [27].

Fully biobased polyester polyols were prepared and used for PU coatings by reacting with diisocyanate. The mechanical, chemical and thermal properties demonstrated that the renewable sources used for the production of PU coatings can be good substitutes for petroleum products [28]. The structural and morphological characteristics of functionalized graphene oxide (FGO)/PU coatings were characterized by transmission electron microscopy (TEM) and scanning electron microscopy (SEM). Beside a chemical reaction between the two components they are able to effectively enhance the thermal, flame retardant and mechanical properties of the coatings [29]. Siloxane-semifluorinated PU coatings were synthesized for robust underwater applications [30].

The state-of-the-art of isocyanates and polyisocyanates of the various PU crosslinking mechanisms and the corresponding applications are presented. Aspects ranging from the replacement of oil-based PU components by biobased equivalents to the development of new synthetic pathways for the production of polyhydroxy polyurethanes for coatings have been also investigated [31]. A study of a PU network of polyaniline, polym- amino phenol and poly-α-anisidine coated on a mild steel panel was reported. The coated films showed excellent corrosion protection in the following order: PU-polyanilin>PU-poly-maminophenol> PU-poly-α-anisidine [32].

As an alternative to PU coatings based on toxic components, the synthesis of poly (hydroxy urethanes) by cyclocarbonate aminolysis constitutes a solution to avoid emissions of volatile organic compounds (VOC)s. Thus, developing their technology became important [33]. Using polyblends of WPU and polyacrylate porous-coated fabrics for synthetic leather were produced. The H bonds between the polymers were proved by FTIR and DSC. The best performance of coated fabrics was found at the ratios from 15/85 to 30/70 polyacrylate /PU [34]. Novel PU coatings were produced by polycondensation of hydroxylationterminated poly (L-lactide) (PLLA) functionalized graphene (G-g-PLLA) and isocyanate terminated PU oligomer with dimethylsiloxane. The functionalized PU was able to hydrolyze in seawater and the hydrolysis rate decreased with the increase of polydimethylsiloxane amount. The new coatings exhibited good antifouling [35].

Polymers containig spirooxazine were grafted and doped with WPU used as an environmentally friendly coating. The obtained films had improved water resistance, mechanical and photochromic properties [36]. TPU was blended in tetrahydrofuran with polyphosphate containing furfuryl and trifluorothoxy groups. Using FTIR, DSC, scanning electron microscopy (SEM) and limited oxygen index (LOI) the obtaining films were analyzed. The results demonstrated that the addition of 20% phosphazene in the blend enhanced the tensile strength by about 110% and decreased the elongation at break by nearly 13% [37].

PU synthesis and film forming using the asymmetric cyclic aliphatic diisocyanate -isophorone diisocyanate with acetylated and pristine partially hydrolyzed amylopectine/white dextrin as a crosslinker has been studied [38]. From isophorone diisocyanate, poly (ethylene glycol), aminopropyl terminated poly (dimethyl siloxane) and 1,4-butandiol via two-step polycondensation, new PU membranes were produced [39]. To obtain a pH responsive hybrid films different amounts of 2-(diethylamino) ethyl methacrylate and PU based on isophorone diisocyanate were used for heavy metal ions removal. The study revealed that functional groups of 2-(diethylamino) ethyl methacrylate are the main sorption sites for the metal ions [40].

Adhesives

A PU powder used as adhesive was synthesized by solution polymerization. The influence of molar ratio of –NCO to –OH, neutralization and types of solution dispersion on the properties of the adhesive were studied. Excellent adhesive properties were found, and that the adhesive thermostability could meet the requirements of industrial gluing for packaging, lining and footwear [41]. A research concluded that WPU could enhance its adhesive characteristics with materials of different natures and structures [42]. A review compares the properties and the use of petrol-based PU with biobased PU for adhesive technology. To reduce the VOCs, PU based on castor oil was preferred as bio raw material [43]. A study insists on the role of accurate selection of diisocyanate -which induces the hard segments- on the viscoelastic and the adhesion properties of PUs. The polyblend studied consists of a mixture of a macrodiol of hydroxyl terminated polybutadiene, polypropylene glycol (PPG) and isophorone diisocyanate necessary to develop the urethane linkages. The controlled quantities of hard and soft segments resulted in better adhesive properties and the balance is realized by the selection of the isophorone diisocyanate [44].

By incorporating synthetic glycerol mono -methacrylate, underwater PU adhesives were produced. The study confirmed that this incorporation induced increasing cohesion and adhesive strength superior to that of pure PU [45]. A new PU sealant for insulating glass based on a nucleophilic substitution reaction between the p-chlorophenol-terminated PU prepolymer and a poly-functional hyper branched polyamine has been synthesized. After crosslinking-curing it was found that the sealant is applicable in a wide temperature range, is not sensitive to moisture, is easy to store, and does not corrode the substrate; all of these as well as its mildew resistance and low cost [46].

PU Elastomers

Poly (ethylene glycol) (PEG) grafted GO was blended with PU elastomer. Their interaction was produced by H bonding. Due to it the strength and toughness of vulcanizate rubber were significantly improved and the blend Tg shifted to higher temperature [47]. Two PU elastomers, one having acylhydrazine (TPIA) and the other disulfide bonds (TPID) were synthesized, and their self-repairable ability and reprocess ability have been investigated. The conclusion of the study was that TPIA elastomer can be repaired under acidic conditions, and the TPID can autorepair under visible light at room temperature [48]. In the case of a polyblend of epoxidized natural rubber/TPU it was found that rice husk ash particles had stronger interactions with epoxidized natural rubber and provided enhanced mechanical properties to the rubber [49]. TPU elastomers having aliphatic polycarbonate soft segments and hard segments made by 1,1’-methanediylbis(4- isocyanato-cyclohexane) or 1,6-diisocyanatohexane and a combination of two chain extenders were synthesized in one-step catalyzed polyaddition [50].

To evaluate the effect of rape seed-oil-based (RO) polyol on the properties of tested urea urethane elastomers (EPUUS) was the objective of a new study. FTIR, thermo gravimetry analysis (TGA), DSC, DMA, static tensile strength and physico-mechanical tests were applied. The use of RO polyol in polyol premixes changed the chemical structure of EPUUS showing a modification in the amount of H-bonds and the degree of phase separation. An increase in Tg of the soft phase was also established [51].

Composites

Thin laminated composite has been produced by blending TPU with low-melting polyester (LMPET) and Kevlar fibers. The presence of Kevlar enhances the tensile properties and flame resistance. The tensile strength of the composite reaches 18.85 MPa and the combustion rate is reduced [52]. The effects of temperature, humidity and automotive fluids on the long-term durability of the two types of glass fiber reinforced PU has been investigated. Variation of mass, flexural strength and viscoelastic response are determined in order to find the changes of the composite [53]. A comparison of TPU/GO and TPU/reduce GO showed that the reduction of GO is not always necessary [54]. The dynamo- mechanical, thermal and mechanical characteristics of long glass fiber reinforced TPU / poly (butylene terephthalate) polyblend have been studied. A good compatibility was found between the two polymers. DMA showed that the TPU content had some influence on dynamic- mechanical properties and the Tg of the long glass fiber reinforced polyblend . DSC indicated that with the increase of TPU amount the crystallization temperature, the melting point and the percent of crystallinity decreased. The TPU presence contributes to a remarkable increase of some mechanical characteristics but also produces a decrease of flexural and modulus of elasticity [55].

Using melt-blending a hybrid made of a shape memory TPU with GO and montmorillonite (MMT) was produced. Thermal analysis showed that GO-MMT enhanced the thermal decomposition of TPU composites [56]. Expandable graphite (EG) is often added to PUs to prevent their flammability. Such graphite was incapsulated in melamine cyanurate and after that was added to rigid PU. It was established that the mechanical properties of the polymer were improved. This composite decomposes faster and produces more smoke than the PU without EG. The obtained data show that melamine cyanurate and EG have a synergistic enhancing effect on the flame retardancy of the composite [57]. A composite made of PU reinforced with sugar palm fiber and glass fiber is recommended to be used in applications that require resistance to high temperature [58]. Carbon fiber-GO reinforcement improved thermo-mechanical and thermal stability of PU due to the carbon fiber- PU improved interfacial interaction as well as the local stiffening of fiber-matrix interphase by the dispersed GO sheets [59].

A PU and red mud composite, the mud in micron particles uniformly embedded in PU, exhibited satisfactory mechanical performance and the compressive and flexural strength are, after complete curing, up to 38.6 and 12.4 MPa. It also displayed very good thermal stability, flame retardancy, storage stability, and reinforcement [60]. The heat conducting with focus on the enhancement of thermal conductivity of WPU composites through compatibility and feasibility of hybrid techniques is reviewed [61]. In a research PU foam was filled with paper waste sludge (5% by foam mass). It was found that the thermal conductivity, water vapor resistance, density, compressive strength, and modulus of elasticity were improved [62].

By using the ring-opening reaction of cyclic carbonate with excess amine and methanol to increase the molar mass of -NHɂ terminated non-isocyanate PU prepolymer, its performance was improved. By adding bisphenol A diglycidyl ether into the prepolymer a hybrid was obtained which has good mechanical properties, a Tg-49,1 ºC and a good thermal stability [63]. Applying a low melting point chain extender, the raw components being 1,4-butanediol and dimethyl propionic acid a study showed that with the decrease of the ratio of dimethyl propionic acid/1,4- butanediol the mechanical properties of the PU decreased [64]. To control the soft segment thermal properties and to enhance tensile strength, shape memory and low temperature flexibility, norbornen was grafted onto PU. This grafted PU demonstrated enhanced low temperature flexibility due to reduce restrictions of rotational and translation mobility [65].

A new molecular design was proposed by incorporating 2-ureido-4-[1H]-pyrimidone motifs in the backbone chains of PU to enhance the mechanical performance and using a triol functional Diels-Alder crosslinker to realize PU healable and recyclable [66]. New PUs made with homocubane (C’ı₀Hı₀O₂)- based diols and diisocyanates were synthesized. They are soluble in polar organic solvents, decompose at relatively high temperature, and the Tg is higher than those of commercial PUs. It is expected that these new polymers will find application in products that need thermally robust PUs [67]. One pot technique for the production of GO/(hyper branched PU)(HPU) has been presented. The composite obtained shows very good increase in the mechanical properties due to the covalent bonding realized between GO and isocyanate component and an excellent load transfer. Mild increase in stability towards thermal degradation and higher dielectric constant compare with HPU at low frequency was also found [68].

The effects of polyhydric alcohols on the mechanical and thermal properties, porosity and air permeability of PU composites have been studied. With increasing polyhydric alcohol amount, the tesile strength and Tg decrease remarkably. The swelling capacity and porosities of the PU/propylene glycol (PPG)-blended and PU/glycerol blended films increased with the increase of PPG or glycerol amount [69]. In composites TPU/wood flour the properties depend on the ratio between the components; it was established that the presence of the wood flower contributes to the increase of important properties such as density, hardness, water absorption, tensile modulus; impact and and abrasion resistance decrease [70]. The high electrical resistivity of blast furnace slag and fly ash make these materials an asset for use in rigid PU foams for insulation [71]. A PU/melamine formaldehide composite foam was prepared through foaming PU. The foam composite showed satisfactory fire retardancy and good comprehensive properties [72].

PU composites which could be used as damping materials with different amounts of hydroxyl silicone oil were prepared. The damping, mechanical properties, thermal stability and molecular groups were established. It was found that the composites with 8% hydroxyl silicone oil possess the best properties [73]. Sandwich composites made of a core of flexible PU foam and nonwoven poly (ethylene terephthalate) as the top and bottom panels were produced. The research found that such composites have functionalities of FR efficacy, acoustic absorption, heat insulation, electromagnetic shielding effectiveness and thus are suited for protective partitions [74].

Flammability

PU foams are in general flammable and their flammability is controlled by using flame-retardants (FR)s. Phenyl phosphonic acid and propylene oxide-based reactive FR polyol, together with limonene based polyol have been used for the preparation of FR/ PU foams. The phosphorous based polyols could be mixed with bio-based polyols to prepare highly fire retardancy and superior physico-mechanical rigid PU foams [75]. The study of a rigid PU foam showed that 3,3’,4,4’-biphenyltetracarboxylic dianhydride and 9,10-dihydro-9-oxa-(10-glycidoxypropilene)-10-phosphaphenantrene- 10-oxide lead to an increase in graphite in the fire residue and the formation of a better barrier to prevent burning by the condensed phase mechanism [76]. Rigid PU modified with microencapsulated red phosphorous, Mg(OH)₂, glass filler and hollow glass bead were prepared and showed that the fire retardancy and the combustion were improved [77].

A new, inherent, fire retardancy of the foams based on imide and oxazolidinone were investigated by LOI , vertical burning test and calorimetry. Cone calorimeter test data showed also that EG reduced the heat release rate (HRR), total heat release ( THR), and total smoke production. A low amount of EG added to PU increased the compression strength but as the amount increases the compression strength decreases [78]. It was found that the EG modified by poly (methyl methacrylate) and poly (glycidyl methacrylate) is an important product as a FR for foams made of PU-polyisocyanurate [79]. FR/ PU foams containing a nonreactive phosphonate (EMD) and EG were produced. This new complex increased the LOI and decreased the total heat release rate ( THRR), average effective combustion heat, peak heat release rate ( PHRR) and total smoke release of the PU foams [80].

New polyols containing 0.8-1.2 wt% boron and 7.9-8.5 wt% nitrogen were used to obtain rigid PU foams. LOI test as horizontal and vertical flammability tests showed reduced flammability and also improved thermal, dimensional stability and mechanical properties [81]. PU foams were also produced by mixing with a phosphorous containing polyether polyol (THPO-PO) and soybean oil-based polyol (SBP).Although the thermal stability of the foams decreased with the increase of THPO-PO amount, the flame retardancy was improved. LOI increased 40% .THPO-PO worked in inhibiting flame and forming phosphorous rich char layer [82]. A polyol made of mercaptenized castor oil and diethyl allyl phosphonate was used for preparing PU foams having different amounts of phosphorous. The closed cells amount in all the foams was above 95%.The results of flammability tests suggest that in the synthesis polyol could act as an essential FR for rigid PU foams ensuring fire safety [83].

The fire characteristics (heat and smoke) were studied using calorimetry test in the case of a composite made of rigid PU foams and flax fibers treated with a FR. The obtained research data showed that treated flax fibers besides improving the mechanical properties of the foam had a good prospect in reducing the fire hazard [84].

A new FR based on a P-N compound namely N,N’’N’’’- tri(diethoxy) phosphoramide (DTP) was synthesized and added to WPU foams. According to TGA data the combination restrained the decomposition, enhanced the residue at high temperature, higher LOI data were obtained and lowered the HRR. The cone calorimetry test indicated that the EG/DTP system jointly inhibited the fire intensity and the smoke production [85].

After a surface modification EG was introduce also in foams based on PU-imide. The foams exhibited outstanding enhancements compare to that of only pristine EG introduction in compressive strength, thermal stability and flame resistance [86]. Four wood-based wastes were incorporated into rigid bio-based PU foams; these were characterized by thermal and combustion properties. Filled PU foams with such wastes showed higher thermal and dimensional stability, however the thermal conductivities and flammabilities were similar to neat foam [87].

Acoustics

Using polycaprolactone diol, toluene diisocyanate, hydroxyl fluorosilicate and 2,4-diamino-3,5-dimethyl thiotoluene, a new Fluor silicon polyester PU was synthesized. The study of its properties indicates that it has an excellent water resistance which has acoustic performance, a low Tg and the fact that it is an ideal transparent product for underwater acoustics [88]. Using linear saturated aliphatic polyesters, methylene diphenyl diisocyanate and other reagents, high performance acoustic damping flexible PUs were produced. The study showed that sound proofing flexible PU foams under optimum conditions can be promising candidates for use as sound-insulating products [89].

With the finite element method PU sound absorbing panels were designed using for material formulation Comsol able to provide optimum performance of echo reduction with minimum thickness. The research shows that by judicious choice of matrix/ filler combination it is possible to achieve selective/broadband absorber for underwater applications [90]. Using Tung oleic acid-base polyol and polyether polyols a new biobased PU foam different from common PU foam was prepared. The study found that the biobased PU mean sound absorption coefficient and transmission loss can reach 0.515 and 21.389 dB [91].

Other Contributions

Fluorinated TPU (FTPU) elastomers based on 3-isocyanatomethyl- 3,5,5-trimethylcyclohexyl isocyanate poly(tetramethyl glycol) polycaprolactone and 4,4’[2,2,2-trifluoro- 1-(trifluoromethyl) ethylidene] bisphenol (BPAF) have been synthesized. The study of their properties showed that the thermal stability and mechanical properties are significantly improved by BPAF [92].

Fluorinated PUs (FPU)s having various amounts of fluorinated chain extender and the same amounts of poly (oxytetramethylene glycol) and diphenyl methane diisocyanate were synthesized in view to find the relationship between surface physico-chemical properties , the bulk microphase separation structures of these FPUs and their antifouling. The conclusion of the study is that the increased microphase separation of FPUs results in enhanced antifouling properties [93]. A WPU prepolymer was obtained based on poly(tetramethyleneglycol), isophorone diisocyanate and 2,2,3,3,4,4-heptafluoro-butyric acid 2,2- bis-hydroxymethylbutyl ester (HFBA) for a series of HFBA/WPUs; ethylenediamine was used as the chain extender. In vitro platelet and erythrocyte adhesion experiments revealed that increasing HFBA content also enhanced the hydrophobicity and reduced blood adhesion to the HFBA/WPUs [94].

The effect of the type of diisocyanates and glycols, degree of crosslinking, the amount of hard segments, crystallinity, the amount of hydrophilic groups on optical properties of WPU have been studied focusing on the matting effect and transmittance. The particle size of PU latex was the most important factor to influence the matting [95]. The effects TPU with various amounts of boron nitride has on DC and AC conductivities and the free volume have been investigated [96]. Results of dielectric/electrical studies of onion-like carbon/PU composite films in very broad frequency and temperature are presented in a study [97]. By studying the spinning technique and the fiber topology, it was found that the characteristics of the PU solutions influence the spinning process and is able to affect the fiber topology [98].

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Fluoropolymers Market Demand, Application, COVID-19 Analysis, Share, Forecast 2023

Fluoropolymers Market Insight

According to a new report by Market Research Future (MRFR), the global market for fluoropolymers is anticipated to touch a revenue of USD 9,912.5 million by the end of 2023 due to rapid industrialization. The market is anticipated to expand at a flourishing CAGR of 5.34 % during the forecasted period (2017-2023). Fluoropolymers offer properties like mechanical insulation and electrical properties, chemical resistance, stress cracking, thermal resistance, and others and are used for applications like industrial films and coatings. Fluoropolymers are also used in construction, household applications and electrical and electronics.

Future Constraints and Drivers Impacting the Market Growth

The increasing demand for lightweight materials in automobile industry coupled with high-quality performance material in architectural coatings is expected to galvanize the growth of fluoropolymers market size globally. Fluoropolymers are highly used as igniters in the aerospace sector along with wafer handling and pipe fittings in the semiconductor industry. With the growing application in the semiconductor and aerospace industry, the global market for fluoropolymer is predicted to expand at a significant rate. Moreover, with the growing consciousness of environmental impacts, there has been an increasing demand for green fluoropolymers which is expected to spur the market growth over the assessment period.

Owing to the lubricity, good dielectric properties, and biocompatibility, fluoropolymers are being used extensively for medical devices which is anticipated to boost the market growth. Fluoropolymers are also used in the development of artificial corneas and heart valves. Fluoropolymers are emerging as one of the extensively used materials due to replacement of plastic products in healthcare and medical industry. It is also used as a substitute for skull, ear, knee, hip, and nose parts owing to its properties like high resistance to heat and chemical, and low coefficient of a fraction. Also, prominent market players are focusing to develop eco-friendly and recyclable polymers which driving the COVID-19 analysis on fluoropolymers market.

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Fluoropolymers Market Competition Analysis

Presence of some of the prominent players like Gujarat Fluorochemicals Ltd (India), DowDupont Inc (U.S.), Arkema Group (France),  W.L. Gore & Associates Inc (Japan), Asahi Glass Co, Ltd (Japan), Kureha Corporation (Japan), 3M (U.S.), Honeywell International Inc. (U.S.), Saint-Gobain S.A. (France), The Chemours Company (U.S.), Daikin Industries Ltd (Japan), Solvay SA(Belgium), Zeus Industrial Products Inc. (U.S), and others, the market is expected to boost significantly over the assessment period.

Global Fluoropolymers Market Segmentation

The global market for fluoropolymers has been segmented based on application, type, end-user, and region.

The market has been segmented into polyvinylidene fluoride (PVDF), ethylene tetrafluoroethylene (ETFE), polychlorotrifluoroethylene (PCTFE), polytetrafluoroethylene (PTFE), fluoroelastomers (FKM), fluorinated ethylene-propylene (FEP), and others based on type. Among these, the polytetrafluoroethylene (PTFE) segment has been predicted to hold the largest share over the assessment period. PTFE held a market share of 45 % as of 2016 and is predicted to showcase 6.94 % CAGR. Polyvinyl chloride is estimated to be the fastest growing segment with 7 % CAGR.

The market has been segmented into films, additives, tubing, paints & coatings, and others based on application. Among these, the paints & coatings segment is witnessed to dominate the market globally over the assessment period and has been accounted for 89.62 kilotons in 2016 and is estimated to showcase 6 % CAGR over the review period.

The market has been further segmented into construction, chemical processing, automotive & transportation, electrical & electronics, household, industrial equipment, medical, and others based on end-use. Among these, chemical processing segment is estimated to generate the highest revenue and is expected to show its dominance during the assessment period. This segment is expected to expand at 6.33 % CAGR during the forecast period (2017-2023).

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Plastic Injection Molding for Medical Devices

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Polytetrafluoroethylene: This plastic material is also known as Teflon. It is resistant to heat and harsh weather conditions and uses pipes to handle corrosive chemicals because of non-corrosion properties.

Perfluoroalkoxy: This material is commonly used for manufacturing laboratory instruments. It is flexible, optically transparent, and chemical inertness.

Fluorinated ethylene propylene: This material is used to produce medical devices that are subjected to weathering like sunlight. It is commonly used in manufacturing containers, packaging films, and breather patches.

Propylene: It is thermoplastic used to manufacture the products that can degrade under the sunlight and remain stable without losing the functionality.

Polycarbonate: It is a versatile material that can withstand heat and cold. The temperature stability of this material makes it ideal to manufacture blood filter housing, centrifugal force separators and syringes.

Should you consider a plastic injection molding manufacturing process for your next medical project?

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Final Say:

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