Multi-component injection molding

Multiple colors or materials combined in an economically efficient manner

Multi-component injection molding brings together several colors or materials in a single mold to improve the design and function of plastic parts. Find out here how multi-component parts can be produced in a single step without joining technology or subsequent assembly and how the injection molding process and robotic systems can be managed centrally in turnkey systems using the SELOGICA control system.


More space, modularity and convenience in multi-component injection molding
ARBURG is launching a new series for efficient multi-component injection molding: the ALLROUNDER MORE machines, which are particularly flexible in their configuration, can be adapted even better to the respective requirements. They offer increased space for larger molds, more modularity in assembly, as well as numerous optimized features for greater ease of use and simple maintenance.

The new machine can be configured to be either an electric or a hybrid model, and offers numerous optimized features for two-component injection molding. A current example is the manufacturing of toothbrushes in hard/soft combination. The increased installation space offers more room for larger molds and convenient mold changes. For the design of the ALLROUNDER MORE, high priority was placed on ease of maintenance. For this reason, the material feed is positioned outside the mold area and the vertical injection unit can be changed quickly using plug-in media connections.

Saw handle

Hard-soft combinations with an attractive tactile surface
A production cell built around a hydraulic ALLROUNDER 570 S uses a 1+1-cavity mold to produce handles for Gardena garden saws from 40% glass fiber-reinforced PP and soft-touch TPE (25% glass fiber-reinforced) in a cycle time of around 35 s.

The injection molding machine is equipped with a compact robot cell: an AGILUS six-axis robot, which moves on an additional linear axis transversely to the machine, is positioned above the moving platen. It removes the handles, transports them to a pad printing station and camera inspection and then sets them down on a conveyor belt. The robotic cell is easy to program thanks to the implemented SELOGICA user interface and, like the mold functions, is integrated in the machine control system.

Cube mould

2-component closure: simultaneous filling, cooling and removal
An innovative cube mold is used for the production of two-component water bottle closures. ARBURG fully integrates mold functions such as servo-electric rotation into the multi-component ALLROUNDER 920 S injection molding machine.

A 32-cavity cube mold from Foboha is used to produce closure caps for five-gallon water bottles. The cycle time is around 10 seconds and the material throughput is over 120 kilograms per hour. Thanks to the four mold sides that can be used during production, mold filling, cooling phase and part demolding can be carried out simultaneously. Compared to conventional molds, the system enables significantly more cavities to be implemented on the same mold mounting surface. This ensures a correspondingly higher production performance and significantly shorter cycle times.

Thumb wheel

Functional part in a single step
The cost-effective manufacture of functional components in a single step is a domain of plastics processing. Thumb wheels for passenger car interiors are a good example: Thanks to a targeted combination of materials, high-quality plastic parts with a soft-touch surface are produced.

The thumb wheels can be produced in a fully automatic process sequence on a hydraulic three-component ALLROUNDER 570 S injection molding machine. This enables efficient high-volume production of these sophisticated functional components. Initially, the translucent main body is produced from PC, then an electroplateable visible surface is added in ABS before a third, attractively tactile TPE component is injected.


Thick-walled optical components
The so-called encapsulation process is suitable for producing high-quality thick-walled lenses in several layers – with shorter cycle times. An automated two-component machine with six-axis robotic system is used.

It makes no difference here whether a lens has been produced in several operations or in only one, component quality is equally high in both cases. Nonetheless, an optical component produced in two stages requires much less cooling time. In the example shown, an electric ALLROUNDER 520 A with a clamping force of 165 tons and a 4+4-cavity mold operates with three stations. The six-axis robotic system removes the finished lenses from the open third station and transfers them to an optical testing station. The cycle time for every four PMMA lenses is only approx. 40 s.

Rotary encoder

Complex electronic component
Three into one: A magnetic disc, carrier plate and protective cap are molded into a functional rotary encoder using the three-component process. The innovative mold concept and the complex automation solution dispense with joining techniques and downstream assembly.

All operations are combined in a single process – including insertion of the sensor and encapsulating with a carrier plate as well as magnetization and assembly injection molding directly in the mold. A fully automated production cell built around a hydraulic ALLROUNDER 370 S injection molding machine featuring three (0.5, 1.4 and 0.5 oz.) injection units.
to the molded part

Button housing

Combined thermoplastic and LSR processing
For the production of a dishwasher keypad, thermoplastic and silicone are processed on an electric ALLDRIVE series injection molding machine to form a hard-soft combination. Here, various material properties can be brought together in a targeted manner and a single production step.

A particular challenge is the joint processing of “hot” and “cold” materials in a single cycle and one mold: the PA must be cooled, while the LSR cross-links at a high temperature. The relevant sections in the mold are consequently separated from one another by means of thermal insulation. This is why transfer technology is particularly suitable here. The molded parts are transferred in the mold via a MULTILIFT robotic system.