Compounding is defined as the
process of incorporating additives, modifiers
into PP for achieving uniformity on a scale
appropriate to the quality of the articles
subsequently made from the compound. It is
also known as hot or melt blending.
Polypropylene (PP) sold for
commercial consumption has some types of additive.
We will define 'unmodified' PP as representing
only those additives without which PP could
not be viably processed in commercial extruders,
moulding machines and the like. Accordingly,
we will define 'modified' PP as that which
has additives designed to provide special
environmental, processing or physical properties.
Typical additives to unmodified PP include
antacids such as calcium stearate, calcium
pelargonate, zinc oxide or hydrocalcite. These
compounds are required to neutralize catalyst
residues that could otherwise form acids detrimental
to the converter's equipment. The second basic
additive to PP is antioxidant. This is required,
as a minimum to protect the polymer from chain
scission during processing and ageing. Typical
process stabilizer antioxidants are hindered
phenols.
Most additional additives and modifiers such as clarifiers, flame retardants etc. are targeted to affect a certain class of properties. Further, fillers and reinforcements are incorporated to impart "Value Addition" to PP. High value added PP products can be made by "Modifying PP with elastomers such as EPM/EPDM.
Value added PP products
* Low-level additives
* Environmental Property Enhancement
In addition to process stabilizers, additional heat stabilizers are used to improve the long term heat ageing of PP. Several antioxidants will afford improvements, with the choice dependant on the environment requires. An important parameter is the continuous use temperature. Typical PP homopolymer with moderate stabilization has a continuous use temperature of 105 deg. c. Special stabilization can increase that temperature to 125 deg. C. Thioethers can act as long term heat stabilizers.
The UV resistance of unmodified PP is poor. However, stabilization can improve its performance significantly. Typically, hindered amines-can be used in combination with other appropriate additives to deliver service life or more than 5 years outdoors in both pigmented and non-pigmented products. This can be done without affecting the appearance of a component. In addition, if a black appearance is acceptable, special grades of carbon black at levels above 2% can provide a service life of more than 20 years.
In addition to the stabilized applications listed above, there are many specialized uses of PP that require low levels of stabilizers. Among the applications for these stabilizers are the protection of PP components in radiation sterilizing environments, the prevention of colour development in various environments and the stabilization of wire-coating resin against the effects of copper. Each of these unique applications requires specific additive packages.
Processing Property Enhancements
In addition to the need for application heat stabilizers, some manufacturing processes require exceptional melt stability. For example, if products will be reprocessed repeatedly, if high levels of scrap are used or if extruded sheet subsequently will be exposed to high temperatures, as in a thermoforming application, the goal would be to minimize degradation in the extrusion process.. In these cases, additional melt stabilizers are required. Phosphite-based products are used for this purpose.
In film resins, slip agents and antiblocks are added to improve the processing and performance characteristics of the film. Slip agents are typically amides, with the particular selection depending on the characteristics being sought. Typical antiblocks are utilized to prevent the film from sticking to itself, while slip agents are utilized to prevent the film from sticking to other surfaces, such as the converting equipment. Also used in film for processing and application performance are antistats. These products act to minimize static build-up as the film passes over the downstream equipment, as well as to minimize the dust pick up inherent in packaged products. For the latter applications, antistats are sometimes incorporated into PP used in sheets, bottles and moulded articles. Monoglycerides and/or diglycerides are typical PP antistats.
Injection moulding products may utilize additives to adjust processing performance in the form of lubricants and/or mould release additives. These additives may interfere with decorating.
Physical Property Enhancements
As crystallinity is responsible for many of the characteristics of PP, he ability to control it allows one to influence the physical properties of the resin. Nucleators are employed that provide sites for the initiation of crystals. The choice of nucleator will determine which properties are affected most significantly. The target properties are usually stiffness and heat deflection temperature, contact clarity and/or see-through clarity. Nucleators may also affect processing performance owing to their effect on the rate of polymer crystallization.
High Level additives (Fillers and Reinforcements for PP)
With the exception of the carbon black at more than 2% level, all the additives mentioned in Section 2.1 are utilized at very low levels. Typically, the total add level of these types of additives will remain below 2%. The properties that are most significantly affected by these type of additives are processing and environmental characteristics. TO achieve significant differences in properties, fillers and reinforcements are used at much higher levels. Fillers and reinforcements are generally distinguished by the resulting differences in properties that they provide to PP.
Fillers are defined as additives in solid
form that differ from polymer matrix with
respect to their composition and structure.
They are generally inorganic in nature and
less frequently organic and are used at levels
of 10% and above. Different types of fillers
can be classified as under:
Inert or Extender Fillers :
These fillers occupy space in the polymer
increase bulk density and lower cost and thereby
extend the polymer. |
Active Fillers : These produce specific
improvements in physical and/or mechanical
properties.
Reinforcements: These are
specific type of active fillers. They increase
tensile strength and flexural modulus of PP.
PP has the capability of accepting large amounts of mineral fillers (upto 70% by weight are marketed as masterbatches). These include various forms of cellulose, hydrated oxides, clays, glass, metal powder, carbon fibre, wollastonite, asbestos, talc calcium carbonate, mica and combinations of these. Each has certain characteristics that it imparts to a PP compound and will be discussed in detail elsewhere.
One of the original aims of introducing fillers was to decrease the cost of polymer by use of inexpensive fillers. However, it soon became apparent that improved properties were possible. This allowed use of high cost fillers, i.e. higher-purity, better colour and special surface treatments to improve adhesion at the dispersed phase interface. The most important fillers for PP are calcium carbonate, talc and mica. Glass fibre is used to reinforce PP.
Therefore, the aim today in compounding fillers
and reinforcements in PP is selective modification
of properties for specified end-use or in
other words "Tailor-Making" of properties.
Selection criteria for fillers and
reinforcements in PP
When incorporating fillers and reinforcements
into PP, a number of factors have to be considered.
These are summarized below:
* Particle shape, mean particle size and particle
size distribution of the fillers
* Dispersability and adhesion (linkage) with
the PP matrix
* Abrasive action of the filler on the processing
machines
* Properties of the filler/reinforcement such
as specific gravity, intrinsic strength, inorganic
impurities.
* Problems associated with dust when handling
fine powders
* Cost of the filler/reinforcement
Reinforcement is justified only when a distinct improvement of properties/cost reduction compared to unreinforced PP is found or when a specific combination of properties is not achievable by other means.
Some general rules for selecting fillers and reinforcements in PP are summarized below:
Property Improvement Sought |
Choice of Filler/Reinforcement |
Improved surface finish |
Calcium carbonate, talc, glass beads |
Improved tensile strength and flexural modulus |
Glass fibres, wollastonite, carbon fibres |
Increased conductivity |
Carbon powder, A1 flakes, Ni-coated mica, stainless steel fibre |
