Achieving low overweight, characterized by excellent wall distribution and a smooth inner bore, is a primary goal for optimizing the cost price per pipe length. While theoretical stiffness calculations exist for pipes, measured values are often higher due to factors like overweight exceeding minimum dimensions. Precise wall thickness control is crucial not only for material cost savings but also for meeting strict product specifications, such as the tolerances required for the rubber ring chamber dimensions in foam core pipes.
Modern pipe extrusion plants leverage advanced technologies to enhance wall thickness control and monitor the pipe profile. Scanners, particularly those allowing operators to adjust settings based on visual feedback on a control screen, represent a significant improvement over older methods. Coupled with loss-in-weight gravimetrics, these systems enable production runs that reliably approach the minimum required wall thickness, saving 1-2% of dry blend material with a payback time often less than one year. Automatic Temperature Centring (ATC) further supports precise control. These Process Control Systems empower operators by freeing them from routine tasks and ensuring production aligns with optimal parameters.
Equipment design plays a fundamental role. Double compression dies are noted for significantly contributing to good wall distribution and a smooth bore. The short land length possible with these dies also improves wall distribution. Screw design, particularly in double screw extruders for PVC, is tailored to the dry blend type, impacting material transport and melt homogeneity, which are foundational for consistent wall thickness. For single screw PO extruders, grooved intakes provide stiff, constant output independent of back pressure, beneficial for control. Proper functioning of dosing feeders is also critical for consistent material feed and preventing issues like insufficient filling or overfilling that can affect output and potentially wall consistency.
The processing of materials also influences the ability to control the final pipe dimensions and quality. Mastering the process, including achieving optimal melt homogeneity and temperature (especially critical for foam core pipes), directly impacts the resulting pipe profile and potential for defects. For instance, uneven melt temperature in foam core production leads to variable expansion and inconsistent wall thickness. Challenges with recycled materials, such as foreign particles, can also impact process stability and require robust extrusion systems to maintain product quality and dimensional control.