Thermoplastic polyurethane

Thermoplastic polyurethane (TPU) is any of a class of polyurethane plastics with many properties, including elasticity, transparency, and resistance to oil, grease and abrasion. Technically, they are thermoplastic elastomers consisting of linear segmented block copolymers composed of hard and soft segments.


TPU is a block copolymer consisting of alternating sequences of hard and soft segments or domains formed by the reaction of (1) diisocyanates with short-chain diols (so-called chain extenders) and (2) diisocyanates with long-chain diols. By varying the ratio, structure and/or molecular weight of the reaction compounds, an enormous variety of different TPU can be produced. This allows urethane chemists to fine-tune the polymer's structure to the desired final properties of the material. For example, a greater ratio of hard to soft segments will result in a more rigid TPU, while the reverse is also true.


The final resin consists of linear polymeric chains in block-structures. Such chains contain low polarity segments which are rather long (called soft segments), alternating with shorter, high polarity segments (called hard segments). Both types of segments are linked together by covalent links so that they actually form block-copolymers.

The polarity of the hard pieces creates a strong attraction between them, which causes a high degree of aggregation and order in this phase, forming [[crystal] a]line or pseudo crystalline areas located in a soft and flexible matrix. This so-called phase separation between both blocks can be more or less important, depending on the polarity and the molecular weight of the flexible chain, the production conditions, etc. The crystalline or pseudo crystalline areas act as physical cross-links, which account for the high elasticity level of TPU, whereas the flexible chains will impart the elongation characteristics to the polymer.

These "pseudo crosslinks", however, disappear under the effect of heat, and thus the classical extrusion, injection molding and calendaring processing methods are applicable to these materials. Consequently, TPU scrap can be reprocessed.


TPU has many applications including automotive instrument panels, caster wheels, power tools, sporting goods, medical devices, drive belts, footwear, inflatable rafts, and a variety of extruded film, sheet and profile applications.[1][2] TPU is also a popular material found in outer cases of mobile electronic devices, such as mobile phones. It is also used to make keyboard protectors for laptops.[3]

TPU is well known for its applications in performance films, wire and cable jacketing, hose and tube, in adhesive and textile coating applications and as an impact modifier of other polymers.[4]

TPU is a common filament material for use in fused filament fabrication 3D printing due to the fact that it is an elastic thermoplastic which makes it ideal for printing objects that need to be flexible and elastic. The fact that TPU is a thermoplastic also allows it to be melted, extruded, then cooled back into a solid which is necessary when 3D printing using fused filament fabrication.

Overview of TPU on the market

Properties of commercially available TPU include:

  • high abrasion resistance
  • low-temperature performance
  • high shear strength
  • high elasticity
  • transparency
  • oil and grease resistance

The currently available TPUs can be divided mainly in two groups, based on soft segment chemistry:

  1. polyester-based TPUs (mainly derived from adipic acid esters)
  2. polyether-based TPUs (mainly based on tetrahydrofuran (THF) ethers). The differences between these two groups are outlined in the table below:

Table of properties

Table 1: Main differences between polyester- and polyether-based TPU.[5]

(A = excellent; B = good; C = acceptable; D = poor; F = very poor)

Property Polyester-based TPU Polyether-based TPU
Abrasion resistanceAC
Mechanical propertiesAB
Low temperature flexibilityCA
Heat agingBD
Hydrolysis resistanceFA
Chemical resistanceAD
Microbial resistanceFB
Adhesion strengthBD

In other words, polyether-based TPU is used only in cases where excellent hydrolysis and microbial resistance is required, as well as in cases where extreme low-temperature flexibility is important.

When stable light colour and non-yellowing performance are required, aliphatic TPU based on aliphatic isocyanates is used.

Recently, BASF has pioneered crosslinking during TPU production, made possible by adding liquid crosslinkers and using a masterbatch. Plant-based bio TPU has been developed for green thermoplastic elastomer applications by Merquinsa and GRECO, marketed as Pearlthane ECO and Isothane respectively...

Trade names

Key commercial brands available are:

See also


  1. "Texin® thermoplastic polyurethane (TPU) resin". Bayer Material Science. Retrieved 2012-02-26.
  2. "Thermoplastic Polyurethane". American Chemical Council. Retrieved 2012-02-26.
  3. Michael, John. "TPU Cases". Cellz. Retrieved 13 November 2014.
  5. "PEARLTHANE". Merquinsa, A Lubrizol Company. Retrieved 2013-01-31.
  6. "BASF - Thermoplastic polyurethane elastomers".
  7. "Merquinsa home page". Merquinsa. Retrieved 18 February 2011.
  8. "Bayer MaterialScience - Thermoplastic Polyurethanes". Bayer. Retrieved 18 February 2011.
  9. "Estane Engineered Polymers". Lubrizol. Retrieved 18 February 2011.
  10. "Lubrizol - Pellethane TPE". Lubrizol. Retrieved 18 February 2011.
  11. "Huntsman TPU: Shaping Your World". Huntsman Corporation. Retrieved 18 February 2011.
  12. "Shin-Etsu Polymor Co., Ltd - Products". Shin-Etsu Chemical. Retrieved 18 February 2011.
  13. "Chemical Products - Laripur - Thermoplastic polyurethanes". COIM Group. Retrieved 18 February 2011.
  14. "GRECO - Thermoplastic polyurethane elastomers". Retrieved 2009-12-26.
  15. Zythane
  16. "3D Printing Materials". LEHVOSS. Retrieved 2018-07-25.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.