Hello and welcome to this blog post on the topic of continuous use temperature (CUT) of thermoplastics.
The maximum acceptable temperature for thermoplastics is one of the most critical requirements to be handled during your material selection. Above the maximum use temperature, mechanical properties (mainly tensile strength and impact strength) or electrical properties (dielectric strength) will drop significantly. On the other hand, long term retention of mechanical and other required properties over the product lifetime is crucial. Therefore, you need to be able to estimate your continuous use temperature.
Don’t worry; there are already methods out there which can assist you. There is the UL 746 which is used to calculate the Relative Temperature Index (RTI; measured in °C).
What is RTI?
Citation UL: “RTI is the temperature in °C, at which properties have decreased to 50% of their initial value after a long-term exposure to this temperature (100,000 hours)”.
The Table 1 below shows the maximum use temperature of 124 most used plastics and can assist you in your daily material selection.
Table 1: Continuous Use / Service Temperature of 124 most used Plastics.
Polymer Name
|
Max Value (°C)
according
UL 746 (RTI)
|
ABS - Acrylonitrile
Butadiene Styrene
|
89.0
|
ABS Flame Retardant
|
95.0
|
ABS High Heat
|
110.0
|
ABS High Impact
|
100.0
|
ABS/PC Blend –
Acrylonitrile
Butadiene Styrene/Polycarbonate Blend
|
110.0
|
ABS/PC Blend 20% Glass
Fiber
|
110.0
|
ABS/PC Flame Retardant
|
110.0
|
ASA - Acrylonitrile
Styrene Acrylate
|
90.0
|
ASA/PC Blend –
Acrylonitrile Styrene
Acrylate/Polycarbonate Blend
|
110.0
|
ASA/PC Flame Retardant
|
110.0
|
ASA/PVC Blend –
Acrylonitrile Styrene
Acrylate/Polyvinyl Chloride Blend
|
90.0
|
CA - Cellulose Acetate
|
95.0
|
CAB - Cellulose
Acetate Butyrate
|
105.0
|
CP - Cellulose
Proprionate
|
105.0
|
CPVC - Chlorinated
Polyvinyl Chloride
|
100.0
|
ECTFE - Ethylene
Chlorotrifluoroethylene
|
150.0
|
ETFE - Ethylene
Tetrafluoroethylene
|
155.0
|
EVA - Ethylene Vinyl
Acetate
|
70.0
|
EVOH - Ethylene Vinyl
Alcohol
|
100.0
|
FEP - Fluorinated
Ethylene Propylene
|
205.0
|
HDPE - High Density
Polyethylene
|
120.0
|
HIPS - High Impact
Polystyrene
|
80.0
|
HIPS Flame Retardant
V0
|
80.0
|
Ionomer
(Ethylene-Methyl Acrylate Copolymer)
|
48.0
|
LCP - Liquid Crystal
Polymer
|
240.0
|
LCP Carbon
Fiber-reinforced
|
240.0
|
LCP Glass
Fiber-reinforced
|
240.0
|
LCP Mineral-filled
|
240.0
|
LDPE - Low Density
Polyethylene
|
100.0
|
LLDPE - Linear Low
Density Polyethylene
|
110.0
|
MABS - Transparent
Acrylonitrile Butadiene Styrene
|
80.0
|
PA 46 - Polyamide 46
|
150.0
|
PA 46, 30% Glass Fiber
|
160.0
|
PA 6 - Polyamide 6
|
120.0
|
PA 6-10 - Polyamide
6-10
|
150.0
|
PA 66 - Polyamide 6-6
|
140.0
|
PA 66, 30% Glass Fiber
|
150.0
|
PA 66, 30% Mineral
filled
|
140.0
|
PA 66, Impact
Modified, 15-30% Glass Fiber
|
140.0
|
PA 66, Impact Modified
|
130.0
|
Polyamide
semi-aromatic
|
135.0
|
PAI - Polyamide-Imide
|
280.0
|
PAI, 30% Glass Fiber
|
220.0
|
PAI, Low Friction
|
220.0
|
PAR - Polyarylate
|
130.0
|
PBT - Polybutylene
Terephthalate
|
140.0
|
PBT, 30% Glass Fiber
|
140.0
|
PC (Polycarbonate)
20-40% Glass Fiber
|
125.0
|
PC (Polycarbonate)
20-40% Glass Fiber Flame Retardant
|
125.0
|
PC - Polycarbonate,
high heat
|
140.0
|
PC/PBT Blend –
Polycarbonate/Polybutylene
Terephthalate Blend
|
121.0
|
PC/PBT blend, Glass
Filled
|
193.0
|
PCL - Polycaprolactone
|
45.0
|
PCTFE -
Polymonochlorotrifluoroethylene
|
175.0
|
PE -
Polyethylene 30% Glass Fiber
|
130.0
|
PEEK -
Polyetheretherketone
|
260.0
|
PEEK 30% Carbon
Fiber-reinforced
|
240.0
|
PEEK 30% Glass
Fiber-reinforced
|
240.0
|
PEI - Polyetherimide
|
170.0
|
PEI, 30% Glass
Fiber-reinforced
|
170.0
|
PEI, Mineral Filled
|
170.0
|
PESU -
Polyethersulfone
|
180.0
|
PESU 10-30% glass
fiber
|
180.0
|
PET - Polyethylene Terephtalate
|
140.0
|
PET, 30% Glass
Fiber-reinforced
|
140.0
|
PET, 30/35% Glass
Fiber-reinforced, Impact Modified
|
140.0
|
PETG - Polyethylene
Terephtalate Glycol
|
63.0
|
PFA - Perfluoroalkoxy
|
260.0
|
PHB-V(5% valerate)
|
95.0
|
PI - Polyimide
|
360.0
|
PMMA - Polymethylmethacrylate/Acrylic
|
90.0
|
PMMA (Acrylic) High
Heat
|
150.0
|
PMMA (Acrylic) Impact
Modified
|
90.0
|
PMP -
Polymethylpentene
|
110.0
|
PMP 30% Glass
Fiber-reinforced
|
110.0
|
PMP Mineral Filled
|
110.0
|
POM - Polyoxymethylene
(Acetal)
|
105.0
|
POM (Acetal) Impact
Modified
|
100.0
|
POM (Acetal) Low
Friction
|
105.0
|
POM (Acetal) Mineral
Filled
|
105.0
|
PP -
Polypropylene 10-20% Glass Fiber
|
130.0
|
PP, 10-40% Mineral
Filled
|
130.0
|
PP, 10-40% Talc Filled
|
130.0
|
PP, 30-40% Glass
Fiber-reinforced
|
130.0
|
PP (Polypropylene)
Copolymer
|
130.0
|
PP (Polypropylene)
Homopolymer
|
130.0
|
PP, Impact Modified
|
115.0
|
PPA - Polyphthalamide
|
140.0
|
PPA, 30%
Mineral-filled
|
156.0
|
PPA, 33% Glass
Fiber-reinforced
|
186.0
|
PPA, 45% Glass
Fiber-reinforced
|
186.0
|
PPE - Polyphenylene
Ether
|
110.0
|
PPE, 30% Glass
Fiber-reinforced
|
110.0
|
PPE, Flame Retardant
|
110.0
|
PPE, Impact Modified
|
110.0
|
PPE, Mineral Filled
|
110.0
|
PPS - Polyphenylene
Sulfide
|
220.0
|
PPS, 20-30% Glass
Fiber-reinforced
|
220.0
|
PPS, 40% Glass
Fiber-reinforced
|
220.0
|
PPS, Conductive
|
220.0
|
PPS, Glass fiber &
Mineral-filled
|
220.0
|
PPSU - Polyphenylene
Sulfone
|
210.0
|
PS (Polystyrene) 30%
glass fiber
|
122.0
|
PS (Polystyrene)
Crystal
|
80.0
|
PS, High Heat
|
90.0
|
PSU - Polysulfone
|
180.0
|
PSU, 30% Glass
finer-reinforced
|
180.0
|
PSU Mineral Filled
|
150.0
|
PTFE -
Polytetrafluoroethylene
|
290.0
|
PTFE, 25% Glass
Fiber-reinforced
|
260.0
|
PVC (Polyvinyl
Chloride), 20% Glass Fiber-reinforced
|
80.0
|
PVC, Plasticized
|
80.0
|
PVC, Plasticized
Filled
|
80.0
|
PVC Rigid
|
80.0
|
PVDC - Polyvinylidene
Chloride
|
90.0
|
PVDF - Polyvinylidene
Fluoride
|
150.0
|
SAN - Styrene
Acrylonitrile
|
95.0
|
SAN, 20% Glass
Fiber-reinforced
|
95.0
|
SMA - Styrene Maleic
Anhydride
|
100.0
|
SMA, 20% Glass
Fiber-reinforced
|
100.0
|
SMA, Flame Retardant
V0
|
100.0
|
SMMA - Styrene Methyl Methacrylate
|
100.0
|
UHMWPE - Ultra High
Molecular Weight Polyethylene
|
130.0
|
XLPE - Crosslinked
Polyethylene
|
82.0
|
Thanks for reading and #findoutaboutplastics
Greetings,
Herwig Juster
Interested to talk with me about your polymer material selection, sustainability, and part design needs - here you can contact me
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Literature:
1. https://omnexus.specialchem.com/2. Saechtling Kunststoff Taschenbuch by Erwin Baur
very helpful - thank you!
ReplyDeleteThanks! Glad to hear! best regards, Herwig Juster
DeleteNice and fast overview. However , to judge relevance, it is important to understand the influence of time, too. RTI is a pretty longterm test, at least compared to many application cases. To be clear, I am not challenging the list, just want to pointout, that it is important to know the requirements to make a more targeted selection. Relying on this list, only, you might end up with quite an expensive material.
ReplyDelete