Tuesday, 1 July 2025

The Melting Point Mystery: Identifying Polyamide 6.6 & 6 with DSC (thermal analysis)

Hello and welcome to a new blog post. Today we are diving into a powerful technique for polymer identification: Differential Scanning Calorimetry (DSC). Specifically, we will explore how DSC can help you distinguish between two common polyamides, Polyamide 6.6 (PA 6.6) and Polyamide 6 (PA 6).

What is DSC?

Differential Scanning Calorimetry (DSC) is a thermal analysis technique used to observe thermal transitions in polymers. This includes identifying key characteristics such as:

  • Glass Transition Temperature (Tg): The temperature at which an amorphous polymer transitions from a rigid, glassy state to a more flexible, rubbery state.
  • Melting Points (Tm): The temperature at which crystalline regions of a semi-crystalline polymer melt.
  • Crystallization and Crystallization Rate: For semi-crystalline polymers, DSC can also reveal information about how they crystallize upon cooling.

The Polyamide Puzzle: PA 6.6 vs. PA 6

Imagine you have a failed injection molded part made of polyamide, but you are unsure if it is PA 6.6 or PA 6. As part of your failure analysis you need to identify the polyamide type. This is where DSC becomes incredibly handy. You can take a small piece of the part, perform a DSC analysis, and the results will provide a clear answer.

Looking at a typical DSC diagram, which plots heat flow over temperature, we can observe distinct differences between PA 6.6 and PA 6 (Figure 1):

Polyamide 6.6 (PA 6.6): This polymer typically exhibits a melting point around 268°C (approximately 270 °C). On the DSC curve, this appears as a clear, sharp peak in the higher temperature range.

Polyamide 6 (PA 6): In contrast, Polyamide 6 has a lower melting point, typically around 220 °C. Its peak will appear distinctly at this lower temperature on the DSC curve.

While both PA 6.6 and PA 6 have similar glass transition temperatures (around 50°C to 70 °C, making them less ideal for differentiation, their melting points provide a robust and clear identification.

Figure 1: Material identification using DSC - Example PA 6.6 vs PA6.

Conclusion

Using DSC to identify PA 6.6 and PA 6 by their distinct melting points is a very practical and effective method. While it requires a laboratory equipped with a DSC instrument, the clarity it provides in material identification can be invaluable for quality control, material verification, and troubleshooting in the plastics industry.

Thanks for reading & #findoutaboutplastics

Greetings, 

Sunday, 22 June 2025

Polymers and the Lindy Effect (Rule of Thumb Plastic Selection and Part Design)

Hello and welcome to a new Rule of Thumb post with focus on the Lindy Effect.

What is the Lindy Effect?

The Lindy Effect, when applied to polymers, suggests that the longer a polymer material or its application has been in use, the longer it is likely to continue to be used in the future. This effect highlights the idea that longevity in the face of time and competition implies robustness and adaptability, making older technologies or materials potentially more durable and relevant than newer, less tested alternatives. 

Examples - Polymers and the Lindy Effect

1. Established Polymer Applications: Consider the long-standing use of polyethylene (PE) in packaging or polyvinyl chloride (PVC) in construction as flame retardant flooring material as well as window frame polymer. The Lindy Effect would imply that these established uses are likely to continue for many years to come, as they have already demonstrated their longevity and reliability (Figure 1). 

Figure 1: Polymers and the Lindy Effect - Examples PVC and PE.

2. Mature Polymer Materials: Similarly, materials like natural rubber or certain types of thermosetting plastics, which have been used for a considerable time, are likely to remain relevant due to their proven track record. 

In essence, the Lindy Effect in the context of polymers suggests that the longer a polymer or its application has been around, the more likely it is to persist into the future. This is because its longevity indicates a degree of robustness and adaptability that makes it a reliable choice in the face of new innovations and changing needs. This brings me to one of my top 10 rules for plastic part design and selection (Rule Nr. 10): Past performance can be guarantee of future results. It can pay of to revisit past application designs to understand what worked in the past (materials selection and design).

Check out more Rules of Thumb in the "Start Here" section.

Thanks for reading & #findoutaboutplastics

Greetings, 
Herwig Juster

[1]  Nassim Nicholas Taleb (2012). Antifragile: Things That Gain from Disorder


Friday, 13 June 2025

High Performance Thermoplastic Selection - Polyether (PPE, PAEK, PEEK, PEKK) [Part 2C]

Hello and welcome to the Part 2C of our High Performance Thermoplastics selection blog series. Today we discuss Polyphenylene Ether (PPE) and PPE blends, their chemistry and production processes, their main properties, processing methods, and applications.

Overview - 6 major high performance thermoplastics families (“the magnificent six”) 

In this blog post series we discuss six major high performance thermoplastics families (“the magnificent six”) which are outlined in the following enumeration

1. Introduction to High Performance Polymers

2. Short profile of the "magnificent six" families:

-Part 2A: Polysulfides (Polyphenylene sulfide - PPS), Polysulfones (PSU, PESU, PPSU), and Polyarylates (PAR)

-Part 2B: Imide-Based Polymers (PEI, PAI, PESI, TPI, PI) and Polybenzimidazoles (PBI, PBI+PEEK, PBI+PEKK)

-Part 2C: Polyether (PPE, PAEK, PEEK, PEKK)

-Part 2D: Liquid Crystal Polymers (LCP) and High-performance Polyesters (Polycyclohexylene terephthalate - PCT)

-Part 2E: Semi- and Fully Aromatic Polyamides (PARA, PPA, Aramid)

-Part 2F: Polyhalogenolefins (PTFE, PCTFE, FEP, PVDF, ECTFE)

Polyphenylene Ether (PPE) and its Blends with Polystyrene (PS) and Polyamide (PA)

Polyphenylene ether (PPE), also known as polyphenylene oxide (PPO), is a high-performance thermoplastic polymer renowned for its excellent thermal, mechanical, and electrical properties. While pure PPE exhibits some processing challenges due to its high melt viscosity, blending it with polystyrene (PS) significantly improves its processability while retaining many of its desirable characteristics. These PPE/PS blends have become commercially significant engineering thermoplastics.   

Jack Welch's team at General Electric faced a challenge with Polyphenylene Oxide (PPO): its extremely high glass transition temperature (208°C) made it difficult to process without degrading the material (the methyl groups of PPE are expected to undergo autoxidation). An important key to future success was the research team around Dan Fox, Allan S. Hay, and E. M. Boldebuck, who found out the miscibility of PPO with PS first. To overcome this, they decided to blend PPO with polystyrene (PS). This clever solution allowed them to maintain many of PPO's desirable properties, lower the glass transition temperature,  while also making the material easier to process at lower temperatures and more cost-effective.

Chemistry and Production Process

1. Chemistry of Polyphenylene Ether (PPE)

The base polymer, PPE, is typically synthesized through an oxidative coupling polymerization of substituted phenols, most commonly 2,6-dimethylphenol (also known as 2,6-xylenol). This reaction is catalyzed by a copper-amine complex in the presence of oxygen. The general chemical structure of PPE can be represented as (Figure 1):

Figure 1: Chemical structure of the polymer Polyphenylene Ether (PPE) [1].

The ether linkages (-O-) in the polymer backbone, along with the aromatic rings and the methyl substituents, contribute to PPE's stiffness, thermal stability, and chemical resistance.

2. Production of PPE/PS Blends

The production of PPE/PS blends primarily involves melt blending the two polymers. This process is typically carried out in extruders or other intensive mixing equipment. The key steps include:
  • Raw Material Preparation: PPE and PS resins are typically received in pellet form. They may be dried to remove any moisture before blending.
  • Melt Blending: The PPE and PS pellets are fed into an extruder, where they are heated and mechanically mixed. The screw design and processing conditions (temperature, screw speed) are crucial for achieving a homogeneous blend. Compatibilizers, such as styrene-butadiene-styrene (SBS) or styrene-ethylene/butylene-styrene (SEBS) block copolymers, are often added to improve the compatibility between the relatively non-polar PS and the more polar PPE. These compatibilizers help to reduce interfacial tension and prevent phase separation, leading to enhanced mechanical properties.
  • Pelletizing: The molten blend exiting the extruder is then cooled and cut into pellets, which are the final product form for subsequent processing by manufacturers.
The ratio of PPE to PS in the blend can be varied to tailor the properties of the final material to specific application requirements. Higher PPE content generally leads to better thermal and mechanical performance, while higher PS content improves processability and reduces cost (Figure 2).   

Figure 2: Changing the glass transition temperature of PPE by changing the ratio of PPE and PS [1].


Main Properties of PPE/PS Blends

PPE/PS blends exhibit a combination of properties derived from both constituent polymers, often enhanced by the presence of compatibilizers. 

Key properties include:
  • Excellent Thermal Stability: PPE inherently possesses high glass transition temperatures (Tg ) and heat deflection temperatures (HDT). Blending with PS can reduce these values compared to pure PPE, however the blends still offer good high-temperature performance compared to many other engineering thermoplastics.   
  • Figure 3 shows the DMA of PPE+PS blend in comparison to High Impact Polystyrene (HIPS) and Polycarbonate (PC). PS has a glass transition temperature of about 100°C and up to this temperature PPE+PS can match PC in thermal performance (PC drops sharply at Tg of 147°C). There is no sharp drop in modulus observed with PPE+PS. 

Figure 3: Dynamic Mechanical Analysis (DMA) of PPE+PS vs HIPS vs PC. 

  • Good Mechanical Strength and Stiffness: PPE contributes to the blend's rigidity and strength. The impact strength can be tailored depending on the blend ratio and the use of impact modifiers.  
  • Excellent Electrical Insulation Properties: PPE is an excellent electrical insulator with a low dielectric constant and high dielectric strength, which are largely retained in the blends.   
  • Good Chemical Resistance: PPE offers good resistance to many chemicals, including acids, bases, and detergents. The chemical resistance of the blend is generally good but can be influenced by the PS content, which is more susceptible to certain solvents.   
  • High Stability towards Hydrolysis: hydrolysis resistance of PPE is superior when compared to other engineering plastics such as PBT and PA.
  • Improved Processability: The addition of PS significantly lowers the melt viscosity of PPE, making the blends easier to process using conventional methods like injection molding and extrusion.   
  • Dimensional Stability: PPE contributes to low water absorption and excellent dimensional stability, which is important for applications requiring tight tolerances.   
  • Flame Retardancy: PPE is inherently flame retardant. Blends often exhibit good flame retardant properties, especially when combined with flame retardant additives.   
Apart from blending PPE with PS; blends out of PPE with PA are possible too. PPE/PA blends have the following advantages: 
  • Combines Key Strengths: Blends the excellent dimensional stability, low water absorption, and heat resistance of PPE with the superior chemical resistance and flow of PA.
  • Enhanced Performance: The resulting material is exceptionally chemically resistant and boasts the stiffness, impact resistance, and heat performance needed for demanding applications like on-line painting.
  • Significant Weight Savings: Unfilled PPE/PA blends can offer part-weight reductions of up to 25% compared to glass or mineral-filled resins, thanks to their low density.
Outperforming properties of PPE/PS blends:  
  • Low specific gravity: 1.1 g/cm3. Most engineering polymers such as PC, PBT, and POM have a specific density of 1.2 g/cm3 and more. 
  • High self-extinguishing property: PPE has a high oxygen index (27-29) and it is easy to add flame resistancy. 
  • Excellent dielectric properties: PPE has a dielectric constant of 2.8 and a dielectric tangent of 6x1E-3. The dielectric breakdown strength (110 MV/m @ 0.5 mm thickness) is the highest among engineering plastics. 
  • High dimensional accuracy: PPE has one of the lowest coefficient of linear thermal expansion among engineering polymers (5.8 x 10E-5 1/°C).
Processing Methods

PPE/PS blends can be processed using various thermoplastic processing techniques, including:
  • Injection Moulding: This is the most common method for producing complex shaped parts from PPE/PS blends, leveraging their improved flow properties compared to pure PPE.
  • Extrusion: These blends can be extruded into profiles, sheets, and films for various applications.  
  • Blow Moulding: Certain grades of PPE/PS blends can be blow molded to produce hollow parts.
  • Thermoforming: Sheets extruded from PPE/PS blends can be thermoformed into various shapes. 
Applications of PPE/PS Blends

The unique combination of properties makes PPE/PS blends suitable for a wide range of applications across various industries:
  • Construction and Plumbing: Applications include pump housings, impellers, and other components requiring good mechanical and chemical resistance.
  • Automotive Industry: Interior and exterior components such as instrument panels, door panels, wheel covers, and electrical connectors benefit from the blends' thermal stability, dimensional stability, and impact resistance.   
  • Electrical and Electronics: Housings for electrical connectors, circuit breakers, switchgear, and other electrical components utilize the excellent electrical insulation properties and flame retardancy of PPE/PS blends.   
  • Household Appliances: Components for washing machines, dishwashers, microwave ovens, and other appliances benefit from the blends' heat resistance, chemical resistance, and good mechanical properties.
  • Business Equipment: Housings and internal components for computers, printers, and other office equipment utilize the blends' dimensional stability, electrical properties, and aesthetic appeal.   
  • Healthcare: Certain grades of PPE/PS blends can be used in medical devices and equipment due to their sterilizability and chemical resistance.   
Trade Names

Several companies market PPE/PS blends under various trade names. Some well-known examples include:
  • Noryl™: Formerly a trademark of GE Plastics, now owned by SABIC Innovative Plastics. This is one of the most widely recognized families of PPE-based resins, including various PPE/PS blends and other modifications.
  • XYRON™ from Japanese chemical company Asahi Kasei.
  • Various manufacturers such as Global Acetal (Lemalloy PPE) produce generic PPE/PS blends with specific property profiles.   
Economic Aspects

The market for PPE/PS blends is significant within the broader engineering thermoplastics market. The demand is driven by the increasing need for high-performance materials in automotive, electronics, plumbing and appliance industries.   
  • Cost Factors: The cost of PPE/PS blends is influenced by the price of the base polymers (PPE and PS), the concentration of PPE in the blend, the type and amount of compatibilizers and additives used, and the manufacturing process. Generally, higher PPE content leads to higher costs.
  • Market Trends: The trend towards lightweighting in the automotive industry and miniaturization in electronics continues to drive the demand for materials like PPE/PS blends that offer a balance of performance and processability. Growing environmental concerns are also pushing for more sustainable material solutions, which may influence the development of new PPE-based blends with recycled content or improved recyclability.
  • Regional Variations: The demand and market dynamics for PPE/PS blends can vary across different geographical regions based on industrial activity and specific application needs.
In conclusion, polyphenylene ether (PPE) and its blends with polystyrene and polyamide represent a versatile class of engineering thermoplastics offering a compelling combination of high-performance properties and improved processability. Their wide range of applications across various industries underscores their economic and technological significance in the world of polymer engineering. As a polymer engineering student, understanding the nuances of these materials will undoubtedly be valuable in your future endeavors.   

In the upcoming Part 2C we will continue to discuss the Polyether high performance polymers such as PAEK, PEEK, and PEKK.

Thanks for reading & #findoutaboutplastics

Greetings, 
Herwig Juster

Literature: 

[1] Allan S. Hay: Polymerization by Oxidative Coupling: Discovery and Commercialization of PPO and Noryl Resins

[2] https://www.sabic.com/en/products/specialties/noryl-resins

[3] https://www.gpac.co.jp/en/product/lemalloy/

[4] https://www.findoutaboutplastics.com/2016/09/jack-welch-and-his-uprise-in-ge.html

[5] https://www.findoutaboutplastics.com/2024/08/high-performance-thermoplastic.html


Friday, 6 June 2025

The Sticky Truth About Gluing Plastics: Why Surface Energy Matters (Plastics Processing Rule of Thumb)

Hello and welcome to todays post focusing on gluing plastics.  Ever tried to glue two pieces of plastic together, only for the bond to fail miserably? You're not alone! Gluing plastics can be surprisingly tricky, and a key factor often overlooked is something called surface energy. Think of surface energy as how "eager" a material's surface is to bond with something else. And when it comes to adhesives, eagerness is a good thing!

The Rule of Thumb: High Surface Energy = Stronger Bonds

Here's the golden rule for gluing: the higher the surface energy of a material, the greater the strength of the adhesion you can achieve.

Imagine a tiny water droplet on a surface. On a highly energetic surface, the water spreads out, trying to maximize its contact. On a low energy surface, it beads up, shrinking away. Adhesives behave similarly. They want to spread out and "wet" the surface completely to form a strong bond.

Diving Deeper: High vs. Low Surface Energy Plastics

Plastics are generally categorized into two main groups when it comes to surface energy:

  • High Surface Energy (HSE) Plastics: These plastics are generally easier to bond. Their surfaces are more receptive to adhesives, allowing for better "wetting" and stronger molecular interactions.
  • Low Surface Energy (LSE) Plastics: These are the notorious "difficult-to-glue" plastics. Their surfaces are less receptive, causing many common adhesives to bead up and struggle to form a lasting bond.

A Quick Look at Surface Energy Values (mJ/m²)

To give you a better idea, below is a small table (Table 1) with approximate surface energy values for some common plastics and other materials. Remember, these values are guides, and specific formulations can impact them.

Table 1: Overview of surface energy values of plastics [1].

As you can see, materials like PTFE (often known as Teflon) have very low surface energy, making them incredibly challenging to bond without specialized adhesives or surface treatments. Another example is the high performance polymer PPS. The surface energy of untreated polyphenylene sulfide (PPS) is typically around 38 mJ/m2. This relatively low surface energy makes PPS challenging to bond to other materials without surface treatment. However, PPS can be treated to increase its surface energy, such as through plasma treatments, which can raise the surface energy to 38 mJ/m2 or higher, depending on the treatment method. In contrast, materials like Polyimide are much more accommodating.

What Does This Mean for Your Next Plastics Gluing Project?

When you're facing a plastic gluing challenge, keep this rule of thumb in mind:

  1. Material selection: list gluing as a post-processing operation during part requirement analysis.
  2. Identify the Plastic: If you know the type of plastic, you can often infer its surface energy.
  3. Opt for HSE Plastics When Possible: If you have a choice of materials, pick higher surface energy plastics for easier and more reliable bonds.
  4. Specialized Adhesives for LSE Plastics: For low surface energy plastics, don't reach for your all-purpose super glue. You'll likely need specialized adhesives designed for LSE materials, or consider surface preparation techniques (like primers or plasma treatment) to temporarily increase the surface energy.

Conclusiones

Understanding surface energy is a game-changer for anyone working with adhesives and plastics. By keeping this simple principle in mind, you'll significantly improve your chances of achieving strong, long-lasting bonds and avoid those frustrating gluing failures. Happy gluing!