A comparison of the thermoformability of a PPE/PP blend with thermoformable ABS. Part I: Small deformation methods

Abstract: Different factors important in ascertaining the thermoformability of polymeric materials are identified and defined. These include resistance to sag, ease of flow, mold replication, deep draw capability, sensitivity to thermoforming temperature and speed, uniformity of thickness distribution, and post‐forming shrinkage and dimensional stability. Methods to study these properties can be classified into small deformation and large deformation methods. The small deformation methods, which are the subject of this … Show more

“…No significant difference in product quality is observed at different sheet heating temperatures of 130 C and 140 C. This can be attributed to the amorphous nature of HIPS. 16 Funding This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.…”

Studies on the stretching behaviour of medium gauge high impact polystyrene sheets during positive thermoforming

“…No significant difference in product quality is observed at different sheet heating temperatures of 130 C and 140 C. This can be attributed to the amorphous nature of HIPS. 16 Funding This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.…”

Studies on the stretching behaviour of medium gauge high impact polystyrene sheets during positive thermoforming

“…On the other hand, slower forming rate promotes relaxation of polymer chains and reduces amount of residual stress. Since lower residual stress results in better dimensional stability in thermoformed parts, slower forming at low temperatures are desirable [3]. However, slow forming leads to longer application periods and very low mold temperatures yields problems in appearance of thermoformed part.…”

“…Thermoformability which depends on thermo-mechanical and rheological properties of polymeric material is the main restriction on implementation of the procedure. Morye [3] defined different aspects of thermoformability as resistance to sag, ease of flow, mold replication, deep draw capability, sensitivity to thermoforming temperature and speed, uniformity of thickness distribution, and post-forming shrinkage and dimensional stability. Reliable estimation of thermoformability of materials and optimum thermoforming conditions are essential for the procedure.…”

Micro-deformation mechanisms in thermoformed alumina trihydrate reinforced poly(methyl methacrylate)

“…Thus, hot compaction can been used for instance to consolidate ultra‐light ultra‐high‐molecular‐weight polyethylene panels for the fabrication of fully thermoplastic composites, where the material is able to retain its high molecular orientation and tensile behavior . Properties of particular relevance when operating in the semifluid state include high melt strength to increase the drawing capability, along with high plastic strain and short characteristic stress relaxation time which provide dimensional stability .…”

“…The processing of polymer pellets as described above requires temperatures greatly in excess of the melting temperature (T m ), in the order of T m + 80 C to T m + 100 C. Alternatively, if the starting material is a semifinished product such as polymer blanks or sheets, processing techniques like thermoforming or hot compaction are employed, which can be operated at temperatures in the order of T m + 20 C to T m + 40 C. This kind of processing only induces a semifluid state in the material, where the viscoelastic behavior of the polymer greatly influences its processability [5,6]. Thus, hot compaction can been used for instance to consolidate ultra-light ultra-high-molecular-weight polyethylene panels for the fabrication of fully thermoplastic composites, where the material is able to retain its high molecular orientation and tensile behavior [7].…”

Deformation Phenomena of Thermoplastic Materials in the Solid and Semifluid States