If you’re looking to achieve a splash of colour, texture or even anti-bacterial into your plastic components, chances are your moulder is using masterbatch in the mix. With the global masterbatch market set to increase in value to USD 15 billion by [i], Thomas Catinat, Operations Manager at Broanmain Plastics explains why masterbatch is so popular and how as a moulder they go about achieving the perfect blend to ensure consistency batch-to-batch.
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Masterbatch is commonly divided into five segments - black, white, colour, additive and fillers. Each formulation offers different functions that when distributed evenly through the polymer mix give it its unique plastic fingerprint.
Colour masterbatch is a highly concentrated pigment. Supplied in pellet form rather than powder or liquid, it is blended into plastics to create a range of end-use applications, for example food and beverage packaging, appliances, automotive and pharmaceutical packaging.
Additive masterbatch offers improved performance of plastic products, for instance illumination, UV resistance, anti-oxidants, antimicrobials or anti-static. Filler masterbatch is used to create better properties such as stiffness or a lighter weight polymer. Chalk, for example, is used to bulk out the plastic. Specific fillers can also be added to make a component fire retardant.
Black and white masterbatch are typically used in building and construction, automotive, consumer goods and domestic appliances.
Achieving a special effect, such as chrome, wood grain, stone, marbling and even sparkle is also possible. These types of compounds are often used to boost consumer appeal and mimic heavier materials.
Ready mixed or create on demand?
Compounded mixes might be purchased in bulk when creating larger quantities of components. But for many end customers, masterbatch is often the most cost effective way for moulders to create the perfect recipe time and again.
Blended in-house, moulders use volumetric dosing units to automatically mix the material ready for processing. Using granular masterbatch can be a lot less messy than powders or liquid, with fewer health and safety risks from dust or spillages.
The ability to maintain a low stock holding and call up a specific blend when required from an external supplier can be more economical, helping to keep production costs down on short runs.
Universal masterbatch offers convenience, are more readily available from suppliers and work with most polymers. The downside is not all universal masterbatches are compatible with all base materials. Conversely, polymer specific masterbatches are formulated using the same base polymer that it will be blended with. These tend to be bespoke and customised to suit a specific customer’s requirement for pigment colour, as well as special properties like heat stability.
Jet blacks and bright whites
For a number of components, such as electronics, producing the deepest blacks and the purest whites can be more challenging that some think. It requires a high pigmentation concentration, especially to make contemporary products such as mobile phones really stand out. Achieving uniform colour is critical. And although there’s usually a standard range of around 40+, there can be over different masterbatch formulations.
Typically, a white masterbatch is used to add opaqueness or whiteness into plastic products. Different grades of titanium dioxide (TiO2) are applied to reflect or scatter light. As well as outdoor applications, some whites are suitable for food contact plastics. One of the key advantages of the white masterbatch is it has a high rate of dispersion, so can easily incorporate other colourants.
Black masterbatch is good for electro-static conductibility, durability and exposure to extreme weather. That’s why black is used in a lot of functional outdoor plastic applications, such as construction pipes, as it is stronger and lighter than coloured equivalents.
Performance enhancing additives are often added to both black and white masterbatch
Colour matching
Picking the perfect colour is one thing. Ensuring consistency batch-to-batch is quite a science. Everyone sees colour differently. While Newton divided the spectrum into seven named base colours - red, orange, yellow, green, blue, indigo and violet, according to psychophysicists we see tens of millions of different hues and shades. Given this, the human eye cannot be relied upon to match samples accurately.
Once a specific masterbatch has been created, specific formulation details, including colour pigments, raw material ratios, notes and directions are held on a recipe card. A moulder can call up these instructions at any time to ensure production consistency.
Should a recipe card be unavailable, physical samples can also be matched using a light box or spectrophotometer.
Homogenisation of a blend, including the dispersion of the masterbatch during dosing, plays a big role in minimising colour and product performance variations. Most recipes detail the percentage by weight of masterbatch to be applied. Yet, discrepancies can occur. Changing the host polymer or switching suppliers is typically when this might happen. For this reason, moulders tend to stick with the same supplier.
As with all plastic processing, stability is essential. Thermal resistance and durability need to be factored in. It’s precisely for this reason why most processors avoid using a high percentage of recycled plastic mixes for the base polymer. The more plastic is reprocessed, the greater the molecular structure changes. This loss of chemical properties affects the composition and therefore is likely to affect the compatibility of all the ingredients within a blend.
Aesthetics aside, understanding the environment in which the end component will be used is critical. For example, components exposed to direct sunlight will need to use a specific masterbatch to prevent discolouration. The chemistry of some colour pigments may be incompatible with the chemistry of some base polymers. Additionally, other agents, such as fillers, could impact the fusion.
One thing is certain, masterbatch has become integral to modern day plastic processing. Out of all the product types, colour masterbatch is experiencing heavy global demand. This robust growth can be attributed to brand differentiation trends in packaging, FMCG, furniture, construction, agriculture and aerospace. Likewise, black and white mastermatch is being extensively utilised by automotive manufacturers for lighweighting and to improve fuel efficiency.
Just like a paint swatch, new innovations emerge on the market all the time. To trial a different pigment or plastic effect, contact us for advice on what’s new and how a new formulation might impact processing stability.
In the field of Fused Deposition Modeling (FDM) 3D printing, the scope for innovation is virtually limitless. The array of available thermoplastics is large, encompassing materials such as PLA, ABS, TPU, PA6, and PEEK, among others. Each of these materials exists in many forms, specifications, and grades, offering multiple options for various applications.
While 3D-printed objects often fulfill roles in rapid prototyping and functional applications, the potential for customization extends beyond mere form and function. Indeed, the aesthetic aspect—particularly color—plays a critical role in differentiating products. This article explores the nuanced subject of filament customization, with a particular emphasis on the employment of masterbatches to imbue 3D-printing filaments with vibrant and enduring colors.
Pigment colorants play a crucial role in determining the appearance and quality of 3D-printed objects. These colorants are added to the base polymer material to give it a specific hue. Unlike dyes, which dissolve into the material, pigments are insoluble particles that are mixed into the polymer matrix.
The addition of pigments occurs in minimal proportions, yet the impact on the filament's color is significant. One key advantage of pigments is their resistance to various environmental factors, such as light and heat, which contribute to the long-term stability of the product's color. The inert nature of pigments also ensures that they do not interfere with the chemical structure of the polymer, thus maintaining the material's inherent properties. This makes pigments a preferred choice for applications that require both aesthetic appeal and functional integrity.
In summary, pigment colorants are essential in 3D printing, offering both vibrant colors and durability without compromising the material's structural integrity.
Curious about experimenting with pigment colorants? Our Filament Maker can help! Learn more!A polymer masterbatch is a concentrated mixture composed of a base polymer and various additives or agents, such as pigments, fillers, stabilizers, and other processing aids that you want to infuse into your base polymer.
Let’s assume your base polymer is ABS. However, the masterbatch would also be made of ABS, containing a certain concentration of additives. Typically, 2% of the masterbatch is enough to modify the properties of the full batch. We can see it like this: 98% of virgin ABS + 2% of ABS masterbatch = 100% of enhanced ABS. Masterbatches are polymer-specific – an ABS masterbatch cannot be blended into PLA filament.
These masterbatches serve as convenient and efficient methods for incorporating specific properties, colors, or functionalities into polymers during manufacturing. Masterbatches are typically produced via a compounding process, during which the additives are thoroughly mixed and dispersed within the polymer matrix, resulting in a homogenous blend that can be easily incorporated into end products. A small pouch of masterbatch pellets at a lab scale will help you enhance several kilograms of polymer. Masterbatches come with speed and freedom of experimentation.
For more information, please visit red masterbatch.
In the case of pigment masterbatch, the additive in focus is pigment. Pigments are finely ground, colored particles that are inert in the polymer matrix, meaning that the pigment is to be dispersed into the base polymer without reacting chemically. This characteristic is pivotal, as it enables the pigments to maintain their color integrity while weaving seamlessly into the filament's structure.
Pigment masterbatches are precisely formulated mixtures containing a high concentration of pigment dispersed within a compatible polymer carrier. Said carrier acts as a medium for the pigments and facilitates their uniform dispersion within the polymer melt, ensuring consistent and even coloration throughout the final product. By melting inside the extruder, the carrier will release the pigment into the whole matrix, resulting in colored filament.
Pigments are colorful substances ground into very fine powder. Adding pure pigment powder to virgin polymer is possible but challenging. The challenges are:
Certain twin-screw extruders are specialized in such mixing but are not suited for filament making. Sequencing the process into 2 steps is the easiest strategy:
In other words, masterbatches allow you to bypass the pigment addition step and make filament immediately with a single screw extruder.
Inks are similar to masterbatches in the sense that they consist of a medium (water) containing a concentration of pigment. Ink cannot be poured into an extruder since water damages the extrusion process, disturbing the melting process and forming bubbles in the final filament. Other media, like oil, are also incompatible with extrusion since they disrupt friction.
The process of filament extrusion can be divided into 3 phases :
Let’s walk through the process, focusing on what happens to the colorful masterbatch pellets.
As explained above, feeding powders can be challenging, but feeding a pellets+pellets mix is easy. In most cases, 98%wt of the pellets will correspond to virgin polymer, while the remaining 2% will be masterbatch. Because the rest of the process can act as a buffer, there is a tiny bit of room for heterogeneity. Mixing the masterbatch and carrier thoroughly in a jar and feeding the mixed input should result in sufficient homogeneity.
The homogeneously colored filament should be coming out of the nozzle now. It shouldn’t behave much differently from virgin filament. This phase of the extrusion process allows us to tell whether the masterbatch grade is compatible with the polymer grade: numerous bumps on the filament surface indicate a severe melting issue- most likely that the masterbatch is not fully melting. In such ‘bad’ cases, troubleshooting might be possible by adjusting the settings. Otherwise, another masterbatch grade must be tested.
Ready to take your filament customization to the next level? Find out how 3devo’s Filament Extruder can make it easier for you! Learn more!The filament extrusion process relies on feeding, melting, pushing, and then obtaining filament. The mixing happens more or less throughout the whole process since extrusion relies on the rotation of a screw, causing a lot of friction. Melting can be ensured by choosing a masterbatch that is compatible with the carrier and by selecting appropriate settings (mainly screw speed and temperature profile). Some mixing happens in the early stages of the process, but especially at one crucial moment.
Mixing liquids is a lot more efficient than mixing solids in terms of homogeneity. Plastic is liquid in the last zone of the barrel–metering zone; as explained above, the tip of the screw is the main point of focus.
Traditional single-screw extruders are equipped with ‘smooth’ screw tips, perfectly designed for stability. Some extruders are designed with a special mixing screw tip. Different types of mixing tips exist, though all of them aim at the same effect: generate turbulence to mix the liquid flow.
Mainly one thing: incompatibility. Incompatibility between the masterbatch and base polymer.
It will often take the form of melting issues during filament extrusion. Typically, big bumps are visible on the filament surface, corresponding to unmelted particles. Some masterbatch pellets might be melting only partially or not at all. When monitoring extrusion data, you might also be able to spot instabilities in the motor behavior, overall flow speed, and of course, filament thickness.
This is a severe issue, especially when undetected and especially when it comes to 3D printing. Classic printheads being equipped with a 0.4mm nozzle, they would clog easily when a huge 1mm inconsistency will try to pass through. The goal of extrusion is to result in a very smooth filament, stable in tolerance and homogeneous in composition.
The lack of melting can be due to inappropriate settings that do not allow the masterbatch to melt. For example, insufficient temperature or insufficient friction. Or perhaps the carrier melts properly on its own but is just incompatible with the masterbatch.
In order to favor melting, there are two options, mainly: increasing the temperatures to provide more conductive heat to the barrel or reducing the temperatures while increasing the screw speed. The second option is a bit counter-intuitive but is a fun example of how extrusion works. Reducing extrusion temperatures and increasing the screw speed will generate more friction inside the barrel, ultimately resulting in more heat and better melting.
Not all masterbatches are equal. Each brand is different, and so is each color. There are obviously differences between brands and suppliers, but there is more. Each individual pigment is a substance that gives color but can also alter the mechanical or melting behavior significantly.
For example, white pigment often consists of titanium dioxide and is notoriously difficult to melt. White masterbatch, therefore, often causes unmelting issues.
In other words, your ABS might be compatible with the green masterbatch from a given supplier but not with the black one, just as an example.
It’s about finding a trusted base carrier and a high-quality masterbatch and then running a compatibility test. Once you find both as well as optimal filament making parameters, extruding colorful filament will be a breeze.
The final limitation is long-term instability or mass production repeatability. Because feeding masterbatch pellets + carrier pellets into a single-screw lab-scale extruder is technically not as accurate in the long run as a dedicated industrial installation running 24/7 for weeks or months, one might detect slight differences between several spools produced at different moments.
The color gradient will most likely not be visible to the naked eye but might exist. This is the little drawback that comes with great process speed and agility.
When it comes to pigment selection, one factor often overlooked is the environmental impact. As we collectively gravitate towards sustainability, considering the eco-friendliness of pigments becomes crucial. Some pigments, especially older formulations using heavy metals like cadmium, can be detrimental to the environment. Therefore, opting for pigments free from toxic substances makes your filament more marketable and contributes to responsible manufacturing. This is especially pertinent given the rising interest in sustainable materials, a topic many competitors don't address.
Masterbatches are easy to use while still giving the user great freedom to experiment and explore. For example, adjusting the masterbatch dose finely can help you create translucent filament: colorful but still transparent. For example, when the manufacturer recommends 2-4%wt, 0.5% or 1% might do the trick.
There is always a saturation threshold. There is no need to throw in 20% of masterbatch – saturation will probably cap at 4%, and 20% might cause severe melting issues.
‘Rainbow’ or multicolored filament can be created by preparing multiple small batches of various colors and then feeding them one after the other in the Filament Maker. There is a certain inertia to the process. Since extrusion relies on continuous mixing, transitions between batches are never instantaneous. However, this can result in multiple colors on the same spool or a gradient of a single color.
In conclusion, the use of masterbatches to infuse captivating colors into 3D printing filaments offers a realm of creativity and personalization. These concentrated mixtures, containing base polymers and additives, seamlessly introduce specific properties and colors during manufacturing. Pigment masterbatches, especially, play a vital role by dispersing finely ground pigments uniformly within the filament, resulting in consistent and appealing colors.
During filament extrusion, careful settings and mixing screw tips ensure proper melting and mixing, although challenges of incompatibility can lead to melting issues. Despite these challenges, masterbatch-based filament personalization allows for experimentation in creating translucent filaments or multicolored gradients.
The journey of infusing color into filaments celebrates both technical prowess and creative imagination. The art of giving color to 3D printing filament, facilitated by masterbatches, harmonizes science and creativity, offering endless possibilities for users to express their visions vividly.
Why not go even further? Let’s look at the whole bright picture and the many doors unlocked by the process of Filament Making. One can now process custom exotic polymers that maybe don’t exist in filament form on the market. Enhance filament with functional additives (carbon fiber, eggshell…). And give it a color just as special as its properties and recycle it.
If you are looking for more details, kindly visit best color masterbatch.