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Your Position: Home - Hardware - What is plastic injection molding and how does it work?

What is plastic injection molding and how does it work?

Author: Helen

Mar. 08, 2024

Hardware

What is plastic injection molding and how does it work?

Plastic components are used in many industries. From automotive to home appliances and medical devices, components in a variety of plastics are used to protect, enhance and build a huge range of products. 

With its reliable, high-quality performance, injection molding is one of the most common processes used to produce plastic components. Indeed, the compound annual growth rate (CAGR) of the injection molded plastics market is expected to increase by 4.6% up to 2028.

Yet, despite its ability to produce high numbers of plastic components quickly, the injection molding process must be tightly controlled to maintain the quality of the final parts. This article will explain how injection molding works and how experienced manufacturers control the process to produce the best quality plastic components. We'll cover:

  • What is plastic injection molding?
  • How does the injection molding process work?
  • Injection molding at Essentra

Injection molding is a complex manufacturing process. Using a specialized hydraulic or electric machine, the process melts, injects and sets plastic into the shape of a metal mold that’s fitted into the machine.

Plastic injection molding is the most widely used components manufacturing process for a variety of reasons, including:

  • Flexibility: manufacturers can choose the plastic injection mold design and type of thermoplastic that’s used for each component. This means the injection molding process can produce a variety of components, including parts that are complex and highly detailed.
  • Efficiency: once the process has been set up and tested, injection molding machines can meet high volume production. Using electric injection molding machines also makes the process relatively energy efficient.
  • Consistency: if the process parameters are tightly controlled, the injection molding process can produce thousands of plastic parts quickly at a consistent quality.
  • Cost-effectiveness: once the mold (which is the most expensive element) has been built, the cost of production per component is relatively low, particularly if created in high volumes for mass production.
  • Quality: whether manufacturers are looking for strong, tensile or highly detailed components, the injection molding process is able to produce them at a high quality repeatedly.

This cost-effectiveness, efficient production time and component quality are just some of the reasons why many industries choose to use injection molded parts for their products.

As well as the fact that plastic injection molding process can be optimized to have a lower carbon impact. Find out more in our guide, Design for Sustainability: Optimizing Plastic Injection Molding Processes.

How does the plastic injection molding process work?

The injection molding cycle includes many parameters which need to be tightly controlled to ensure the overall quality of the plastic components produced. Understanding the process and parameters in some depth will help manufacturers to identify plastic components producers who can provide the quality and consistency they need.

Step 1: selecting the right thermoplastic and mold

Before the actual process begins, it’s key that the right thermoplastics and plastic injection molds are selected or created, as these are the essential elements that create and form the final components. Indeed, to make the right selection, manufacturers need to consider how the thermoplastic and mold interact together, as certain types of plastics might not be suitable for particular mold designs.

Each mold tool is made up of two parts: the mold cavity and the core. The mold cavity is a fixed part that the plastic is injected into, and the core is a moving part that fits into the cavity to help form the component’s final shape. Depending on requirements, mold tools can be designed to produce multiple or complex components. The repeated high pressures and temperatures that mold tools are put under mean they are typically made from steel or aluminum.

Due to the high level of design and quality of materials involved, developing mold tools is a long and expensive process. Hence, before creating a final bespoke mold, it’s recommended that tools are created, prototyped and tested using computer aided design (CAD) and 3D printing technology. These tools can be used to digitally develop or create a prototype mold that can then be tested in the machine with the chosen thermoplastic.

Learn more about how 3D printing can complement the injection molding process.

Testing the tool with the right thermoplastic is key to ensuring that the final component has the right properties. Each thermoplastic offers different characteristics, temperature and pressure resistances due to their molecular structure. Plastics with an ordered molecular structure are called semi-crystalline and those with a looser structure are known as amorphous plastics.

Each plastic’s mechanical properties will make them appropriate for use in certain molds and components. The most common thermoplastics used in injection molding and their characteristics include:

  • Acrylonitrile-Butadiene-Styrene (ABS) – with a smooth, rigid and tough finish, ABS is great for components that require tensile strength and stability. Find out more in our guide PVC vs ABS.
  • Nylons (PA) – available in a range of types, different nylons offer various properties. Typically, nylons have good temperature and good chemical resistance and can absorb moisture. Read more about nylons in Nylon 6 vs Nylon 6/6.
  • Polycarbonate (PC) – a high-performance plastic, PC is lightweight, has high impact strength and stability, alongside some good electrical properties.
  • Polypropylene (PP) – with good fatigue and heat resistance, PP is semi-rigid, translucent and tough. Find out more in our guide PP vs PE.

The final thermoplastic selection will depend on the characteristics that manufacturers need from their final component and the design of the mold tool. For example, if a manufacturer needs a lightweight part with electrical properties, then PC will be appropriate, but only if the mold doesn’t need to operate above 275°F (135°C) or at very high pressures, which the plastic won’t be able to resist.

Once the right thermoplastic and mold have been tested and selected, the injection molding process can begin.

Step 2: feeding and melting the thermoplastic

Injection molding machines can be powered by either hydraulics or electricity. Increasingly, Essentra is replacing its hydraulic machines with electric-powered injection molding machines, showing significant cost and energy savings.

Injection molding machines consist of a feeder or ‘hopper’ at the top of the machine; a long, cylindrical heated barrel, which a large injection screw sits in; a gate, which sits at the end of the barrel; and the chosen mold tool, which the gate is connected to.

To start the process, raw plastic pellets of the thermoplastic material are fed into the hopper at the top of the machine. This could be virgin material, like plastic resin, or recycled plastic materials. As the screw turns, these plastic pellets are fed gradually into the barrel of the machine. The turning of the screw and the heat from the barrel gradually warm and melt the thermoplastic to melting point until it turns to a molten material.

Maintaining the right temperatures within this part of the process is key to ensuring the plastic can be injected efficiently and the final plastic part formed accurately for the injection molding project.

Step 3: injecting the plastic into the mold

Once the melted plastic reaches the end of the barrel, the gate (which controls the injection of plastic) closes and the screw moves back. This draws through a set amount of plastic and builds up the pressure in the reciprocating screw ready for injection. At the same time, the mold halves close together and are held under high pressure, known as clamp pressure.

Injection pressure and clamp pressure must be balanced to ensure the part forms correctly and that no plastic escapes the tool during injection. Once the right pressure in the tool and screw is reached, the gate opens, the screw moves forward, and the molten plastic is injected into the mold.

Step 4: holding and cooling time

Once most of the plastic is injected into the mold, it is held under pressure for a set period. This is known as ‘holding time’ and can range from milliseconds to minutes depending on the type of thermoplastic and complexity of the part. This holding time is key to ensuring that the plastic packs out the tool and is formed correctly.

After the holding phase, the screw draws back, releasing pressure and allowing the part to cool in the mold and the plastic solidifies. This is known as ‘cooling time’, it can also range from a few seconds to some minutes and ensures that the component sets correctly before being ejected and finished on the production line.

Step 5: ejection and finishing processes

After the holding and cooling times have passed and the part is mostly formed, ejector pins or plates eject the parts from the tool. These drop into a compartment or onto a conveyor belt at the bottom of the machine. In some cases, finishing processes such as polishing, dying or removing excess plastic (known as spurs) may be required, which can be completed by other machinery or operators. Once these processes are complete, the components will be ready to be packed up and distributed to manufacturers.

Injection molding at Essentra

At Essentra, injection molding is a key production process. As part of our ESG strategy, we are optimizing our plastic injection molding processes, including replacing old hydraulic machines with electric machinery.

We continue to invest in material innovation and have a new Centre Of Excellence at our UK headquarters, which will help us to test and develop new materials that will in turn enable us to offer even more sustainable product ranges globally for our customers.

Our team of experts are on hand to help you create consistent, high quality parts for your next project. With over 45,000 molds to choose from and custom solutions available, we can deliver the parts you need. As well as plastic parts, we also have a range of metal components manufactured using hot chamber die casting.

Free CADs are available for most solutions, which you can download. You can also request free samples (some exclusions apply) to make sure you’ve chosen the right product for what you need.  Same day dispatch for sample requests received by 4pm.

If you’re not quite sure which solution will work best for your application, our experts are always happy to advise you.

Request your samples or download free CADs now.

Questions?

Email us at sales@essentracomponents.com or speak to one of our experts for further information on the ideal solution for your application 800-847-0486.

What are plastic Molding dies?

  • The industry of making plastics relies heavily on plastic moulding dies. It is employed to mould plastic into different forms and shapes. Accuracy, adaptability, cost-effectiveness, and the capacity to create complicated forms are just a few benefits that plastic moulding dies may provide. They also make for speedy and effective manufacturing because they are simple to operate and maintain. Plastic pellets are heated and injected into a mould during the used plastic injection moulding process. 
  • The plastic is then injected out of the mould when it has cooled. Common applications for this method include the mass production of plastic components for the automotive, electrical, and medical sectors. Utilized plastic injection moulding is a practical method that may be utilized to create parts of a high standard. Additionally, it enables exact sizes and forms that are challenging to produce using standard production procedures.

The Origins of Used Plastic Injection Molding:

The history of used plastic injection moulding began in the late 19th century. John Wesley Hyatt invented the technique and utilized it to make billiard balls. Since then, the method has grown in popularity and is currently utilized in various sectors. Today, one of the most widely utilized production techniques worldwide is plastic injection moulding. This technique is thought to create more than 3 billion pieces annually. Compared to other production techniques, used plastic injection moulding has a lot of benefits. It is affordable, quick, and capable of accurately producing components of any size and form. Additionally, it enables accuracy and reproducibility, which are crucial for making components in large quantities. Used plastic injection moulding is excellent for creating difficult, intricately detailed objects. Because of this, it excels in various applications, from medical equipment to automobile parts.

The Technique of Injection Molding Used Plastic:

Injection moulding of discarded plastic is a multi-step technique. An injection of molten plastic resin into a mould comes first. The plastic is then injected out of the mould when it has cooled. After that, the part is cut, examined, and packed. Used plastic injection moulding is a comparatively quick and easy operation. It may be utilized to make pieces of any size and shape accurately.

The Plastic Molding Method Used by the Chinese:

  • The selection of the resin involves a great deal of planning. Before entering the moulding machine, the liquid resin undergoes a lengthy preparation procedure. Any contaminant might hamper the entire production process. The machine carries out each stage after entering the moulding machine. As the term implies, liquid resin is "injected" into the molds.
  • For producers in China, plastic moulding is a creative field. Chinese businesses are committed to offering cutting-edge plastic components and want to do it with less wasted time. The moulding process starts long before the raw ingredients arrive at the production facility. 
  • Most moulds are constructed before the moulding procedure; a standard moulding design is developed for mass manufacturing. The resin begins to solidify as soon as it is introduced into the heated molten state. The mould can cool down by being frozen in position. Moulds have an attractive visual opening.
  • You will realize that the experience is fantastic if you ever get the chance to observe a mould opening. The visual ASMR impact of seeing a mould take shape before your eyes. After the mould is created, the moulding process continues. Before they are delivered to the consumer, the mould must undergo rigorous chemical processing.
  • China is experimenting with new limits in the production of plastic moulding. A few Chinese businesses have introduced 3D printers already embedded into their moulding equipment. The way moulds are viewed reinvented by a prototype mould. With their ingenuity and modernity, Chinese manufacturers continue to set a standard for the sector.

The Use of Moulding Die Machines:

 Plastic moulding dies are one of the biggest assets different companies have. Its domain isn’t limited to only a few industries; almost every manufacturer can use this machine. The benefit of using a plastic mould die is that it lets you create complex parts and materials in bulk form. And that is basically why a moulding die is used.

A moulding die machine's components:

If we discuss the appearance of an injection mould die tool, it is a little metal plate with holes. Because it dictates the object's size and form, the die is crucial to the injection moulding process. Usually constructed of steel or aluminum, a die is precisely machined to the requirements of the product. The substance from which the component is to be made is poured into the die from a hopper or vat of molten plastic. The item can be removed from the die after it has been produced and milled down if necessary.

The Moulding Die Machine Process:

The heating unit, winding unit, injection chamber, and injection nozzle are some of the parts that make up these machines. The plastic substance is injected into the injection chamber through the injection nozzle. The plastic is heated until it melts, at which point it pours into the mould cavity through the injection nozzle. The plastic can flow through the injection nozzle and into the mould cavity thanks to the heating unit's ability to regulate the temperature at which it melts. Additionally, it stops the plastic before it enters the chamber from solidifying.

How are injection moulding dies made?

You will require a few materials to create plastic moulding dies, including:

A mold is the opposite of the intended shape, a mould. Metal, ceramic, or even 3D printing may be used to create it.

  • Plastic pellets:

Small particles of plastic called plastic pellets will be melted and fed into the mould.

  • An injection moulding machine:

The plastic pellets will be heated and injected into the mould using an injection moulding machine.

  • A cooling system:

An effective cooling system is required to harden the plastic and cool the mould.

Conclusion:

Our internal design and development staff is quite skilled. When working with clients from other countries, we are confident and informed. ACE offer OEM/ODM services to all clients, and our expert project management and customer support teams are accessible twenty-four hours a day, seven days a week. We have implemented a stringent quality control system to guarantee that our products are of the greatest quality and that we offer the finest service at the most reasonable price.

What is plastic injection molding and how does it work?

What You Need to Know About Plastics Moulding Dies?

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