High Performance Engineering Plastics for Rotating Equipment · 2019. 4. 1. · M-710 NORSOK...

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PumpsCompressorsValves

You inspire … we materialize®

Rotating Equipment:High Performance Engineering Plastics for

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Duratron®

PBIDuratron® PI

Duratron® PAISemitron ® PAI

Semitron® PEIDuratron® PEI

Quadrant® PPSUQuadrant® PSU

Semitron®

PEEK, PTFEKetron® PEEKTechtron® PPSFluorosint® PTFE

Quadrant® PC

PMMAABS

PSPVC

Semitron® POMErtalyte® PET-PNylatron® PA, Ertalon® PAAcetron® POM, Ertacetal® POMTIVAR® UHMW-PE

PE 500Proteus® PPSanalite® HDPE/PPLDPE

AMORPHOUS SEMI-CRYSTALLINE

TEM

PER

ATU

RE

/ PER

FOR

MA

NC

E

460 ºF / 230 ºC

250 ºF / 120 ºC

150 ºF / 65 ºC

1.360.0002.00053206

The global industry leader replacing metals & alloys by delivering STRONGER, LIGHTER-WEIGHT plastic materials with superior corrosion and extreme temperature resistance

kg shipped weekly worldwide

Team members

Branch offices

Countries

R&D Locations

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TABLE OF CONTENTS The global industry leader replacing metals & alloys by delivering STRONGER, LIGHTER-WEIGHT plastic materials with superior corrosion and extreme temperature resistance

About Quadrant 1

Why plastics 3

Pumps 5

Compressors 9

Application Stories 15

Valves & Seals 17

Why Quadrant: The proof is in the data 23

Imperial Data Sheets 31

Metric Data Sheets 33

UPSTREAM MIDSTREAM DOWNSTREAM

Introducing the first and only multiple process stock shapes to receive M-710 NORSOK certification. Quadrant’s Ketron® 1000 PEEK was formulated in cooperation with our oil and gas industry partners to deliver long-lasting maximum performance in the most extreme temperature and high-pressure environments.

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In all areas of the oil, gas & petrochemical industry, engineering and maintenance teams are focused on:

Increasing MTBF (Mean Time Between Failure) Increasing MTBR (Mean Time Between Rebuild) Building equipment that increases the efficiency of a system

– producing more product with the same capital equipment Reducing “cost in use” of new designs and newly rebuilt equipment

These increasing demands mean that some traditional materials just can’t get the job done. For example, materials with an inability to maintain dimensional stability in operation, cause significant losses in efficiency and capacity.

Parts that wear prematurely, cut into your production schedule, and increase operational spending towards reducing their service life. That can mean the obvious losses in production profit.

New choices for new challenges

Quadrant has a proven and growing portfolio of engineering materials for components that handle these challenging conditions.

It includes materials that: Reduce weight and power requirements Survive a wide range of chemicals and abrasives Increase MTBR Outwear standard materials by a factor of 10 or more – while reducing

frictional drag Hold dimensions over wide temperature swings Resist catastrophic upsets/failures––minimizing other hardware

damage.production profit.

To simplify things

A few key properties of engineering plastics – with the optimum design – have a major effect on equipment productivity.

This guide helps simplify the material selection challenge:

It groups materials by their application, product media and temperature capability Each group then compares materials on their physical/mechanical properties It also compares another key factor – relative cost

We back all of this up with tech support, and the most capable network of plastics distribution and service centers in North America.

Valve Seat

Back Up Ring

ANSWERS & EXPERTISE

QUADRANTPLASTICS.COM

LIVE CHAT SUPPORT

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WHY PLASTICS

Material performance improves efficiency and reliability

Quadrant has significant experience in many compressor, valve and pump applications. Our broad range of materials provides the ideal material for each application without compromising performance – or cost. Our materials are selected for these applications for many reasons.

Improved Chemical ResistanceQuadrant’s Advanced Engineering Plastics offer a broad range of fluid chemical resistance. Ketron® PEEK is resistant to most chemicals excluding oxidizing agents. Techtron® PPS has no known solvents below 400˚F (204˚C), and Fluorosint® 500 PTFE is only attacked by molten alkalis and very few other chemicals.

Improved Overall EfficiencyDesign engineers can design and implement polymeric components with reduced running clearances. Reducing wear component clearance by 50% increases output and reduces vibration, and MTBF for typical efficiency gains of 4–5%. (See Fig. 1) Should equipment upsets occur, damage to mating components is negligible, unlike metal components where contact during failure can cause permanent damage.

Reduced Weight & Power RequirementsMaterials from Quadrant have excellent strength-to-weight ratios approaching non-ferrous metals. Engineers can modify designs based on these lighter weight improving installation procedures and reducing overall system weight, which translates into lower power consumption improving output and economics.

Increased MTBR (Mean Time Between Rebuild)When compressors and pumps undergo upset conditions such as suction loss (cavatation), slow rolling or startup conditions, Quadrant’s materials continue to run without issue. These advanced materials do not gall or seize, eliminating damage to expensive mating parts, reducing repair costs while extending time between maintenance and repairs. Advanced Engineering Plastic materials save money for the operator, reduce vibration and eliminate shaft deflection––while increasing seal and bearing life for smoother dynamic operation.

Reduced Frictional DragThe low CLTE and wear resistance of our polymeric materials such as Ketron® HPV PEEK, wear grades of Duratron® PAI and Fluorosint® Enhanced-PTFE eliminate seizures, improves measurable performance ratios, and allows internal rotating to stationary part clearances to be reduce by at least 50%. Quadrant’s Advanced Engineering Plastic materials provide dry running capability while reducing damage from direct contact. Unlike metals, these wear-resistant components do not generate excessive heat when in contact with mating parts during operation, avoiding seizures during periods of suction loss. For example, pumps equipped with many of Quadrant’s materials are able to run dry for extended periods of time while avoiding catastrophic failures and/or premature shutdown, typical of metal pump wear rings.

Reduced VOC EmissionsThese advanced materials are very compliant, and maintain flexibility at temperature extremes from Cryogenic up to 600°F (315°C), allowing for tight shutoff and longer reliable service complying with EPA and European low-emission standards.

TIME

Polymer Labyrinths

Aluminum LabyrinthsEFFIC

IEN

CY

Polymer Seals offer Greater Efficiency & LifeNote: Polymer Labyrinth Seals provide much greater efficiency and provide the increased performance over a much greater service life.

Fig. 1

PUMPS

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Pump applications include impellers, rotors, gears, bushings, washers, vanes, seals and more.

What is a pump?

A PUMP is a machine that moves fluids (either liquids or gases) by mechanical action. Normally we think of PUMPS moving liquids (incompressible fluid). A PUMP moving a gas (compressible fluid) is actually called a COMPRESSOR. There are different types of pumps, some of which are explained below.

DynamicPositive displacementDraws in and captures volume of fluid in a chamber, then mechanically forces that volume to a discharge.

Reciprocating Piston Pump

Rotary Lobe Pump

Axial Pump

Centrifugal Pump

Rotary Screw Pump

Reciprocating:Uses linear shaft movement to move a chamber of fluid.

Centrifugal:Draws fluid in via the center of impeller, then accelerates fluid outward. Fluid then hits casing reducing velocity and increasing pressure.

Rotary:Uses linear shaft movement to move a chamber of fluid.

Axial:Uses a series of blades to force fluid in desired direction. Also sometimes called a propeller pump.

Creates high fluid velocity and converts the velocity topressure in a diffusing flow passage.

Other pumps include vertical, horizontal and process pumps which can all be either Positive

Displacement or Dynamic.

Recommended Temperature Ranges Based on Material’s HDT*

PumpComponent

ANSI & APIPump

Standard

Up to 200°F(Up to 93°C)

200°F - 300°F(93°C - 149°C)

300°F - 400°F(149°C - 204°C)

400°F - 500°F(204°C - 260°C)

Above 500°F(Above 260°C)

ANSI & APIPump

Standard

Casing-CoversImpellerRotorsGears

ANSI B73. 1M

Ertalyte® TX PET-P

Techtron® PPS

Techtron® HPV PPS

Techtron®

PSBG PPS

Ketron® 1000 PEEK

Techtron® PPS

Techtron®

PSBG PPS

Ketron® CM1030HT PEK

Ketron®

CA30 PEEK

Duratron® D7015 PIDuratron® PBI

ANSI B73. 1M

API 610 API 610

API674 API674

Throat &interstage bushings

Line shaft bearingsSleeve-thrust

WashersBearing cages

ANSI B73. 1M

Acetron® GPPOM-C

Fluorosint®

135/ HPV PTFE

Techtron® HPV PPS

Techtron® PSBG PPS

Ketron® HPV PEEK

Ketron® CA30 PEEK

Ketron® HPV PEEK


Duratron® T4301 PAI


Duratron®

T4301 PAI

ANSI B73. 1M

API 610 API 610

API674 API674

VanesCase war rings

Impeller eyeWear rings

ANSI B73. 1M

Fluorosint® 135/ HPV PTFE


Techtron® PSBG PPS


Techtron® PSBG PPS



Duratron® D7015 PI

Duratron® PBI

ANSI B73. 1M

API 610 API 610

API674 API674

Shaft Seals

ANSI B73. 1M

Acetron® GPPOM-C


Techtron® PSBG PPS

Ketron® HPV PEEK

Ketron® CM CA30 PEEK


Duratron®

T4540 PAI

Duratron® D7015 PI

Duratron® PBI

ANSI B73. 1M

API 610 API 610

API674 API674

Lantern ringsLantern restrictors

ANSI B73. 1M

Acetron® GPPOM-C

Techtron® PSBG PPS

Fluorosint®

135/ HPV PTFE

Ketron®

CA30 PEEKKetron® CM1030HT PEK

Duratron® D7015 PI

Duratron® PBI

ANSI B73. 1M

API 610 API 610

API674 API674

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PUMPS

This matrix uses the same customer experiences to group materials by ANSI class—with the added dimension of application *HDT (Heat Deflection Temperature) as measured using ASTM test method D648ANSI B73.1M: American National Standard for Medium Duty Pumps for Chemical Industry Service 300Psig (2,068 kpa) at 300°F (149°C) API 610: American Petroleum Institute Standard for Heavy Duty Pumps for Petroleum Industry Service 750Psig (5,171 kpa) at 500°F (260°C) API 674: American Petroleum Institute Standard for Heavy Duty Pumps for Petroleum Industry Service 10,000Psig (68,000 kpa) at 500°F (260°C)

4.001-5.000 5.001-6.0006.001-7.0007.001-8.0008.001-9.000

101.63 -127.00 127.03 -152.40152.43 -177.80177.83 -203.20203.23 -228.60

0.015 0.38100.017 0.43180.018 0.45720.019 0.48260.020 0.5080

0.0065 0.16510.0080 0.20320.0090 0.22860.0100 0.25400.0105 0.2667

Table 1 - Ketron® CM 1030HT PEK vs API Minimum Diametrical Clearance

Bore Diameter Ketron® CLEARANCE API CLEARANCE

IN MM IN MM IN MM

Reduced wear ring clearance increases pump efficiency, decreases vibration

and allows pumps to run longer. The reduced clearance minimizes recirculation while maintaining the same production flow. When the same amount of power is used and production flow is maintained the efficiency of the pump is increased dramatically. Efficiency gains of 2 to 5% are typical.

Pump application matrix

This pump component material selection matrix was developed using customer feedback and practical application experience. This matrix is inteded to help a designer select a possible material that should satisfy most applications. It does not replace the specific design review and testing that Quadrant advocates for all applications.

COMPRESSORS

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What is a compressor?

A COMPRESSOR is a PUMP that compresses and moves compressible fluids.....aka GAS. There are different types of compressors, some of which are explained below.

Advanced thermoplastics can be used for compressor moving parts, shrouds, and various seals to reduce clearances, prolong wear life, and improve performance and efficiencies.

DynamicPositive displacementDraws in and captures volume of gas in a chamber, then reduces the volume of that chamber to compress the gas.

Piston Compressor

Axial Gas Turbine Compressor

Centrifugal Turbine

Sliding Vane Compressor

Reciprocating:Uses linear shaft movement to compress a chamber of gas.

Centrifugal:Draws air to center of impeller, then accelerates gas outward. Gas then hits a diffuser reducing velocity and increasing pressure.

Rotary:Uses rotating shaft movement to move a chamber which then compresses gas.

Axial:Uses a series of blades to force fluid in desired direction. Also sometimes called a propeller pump.

Speeds up gas to a high velocity, then restricts the gas flow so reduction in velocity causes pressure increase.

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COMPRESSORS

Polymer seals are used for numerous labyrinth styles including: Shaft Seals Impeller Eye Seals Balance Piston Seals Secondary Seals Gas Seals

Material Selection is Dependent on: Process Temperature Pressure Chemical Exposure / Process Fluid Seal Design

- Tooth on Rotor & Tooth on Stator

Three Common Thermoplastics Selected for Use as Labyrinth Seals...Duratron® PAI Ketron® PEEK Fluorosint® PTFE

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Duratron® PAIHDT = 280°C / 543°F

Ketron® PEEKHDT = up to 250°C / 480°F

Fluorosint® PTFEHDT = 132°C / 270°F

Thermoplastic Labyrinth Seals: Improved Performance in Rotating Compressors

Polymer seals offer reduced shaft clearance equating to less leakage of process gases and higher efficiencies. Self-lubricating polymers also offer longer service life compared to their metal counterparts equating to significant increases in system efficiencies. We back all of this up with tech support, and the most capable network of plastics distribution and service centers in North America.

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Ketron CM 1030HT PEKKetron CM CA30 PEEKDuratron T4540 PAIFluorosint 500 PTFE

550-50 50 150 250 350 4500

Temperature

QUADRANT ADVANCED MATERIALS - DMA CURVES

Dyn

amic

Mod

ulus

650

600

400

200

800

1000

1200

1400

1600

1,379

2,758

4,137

5,518

8,274

9, 653

11,032

MPa kpsi

6,895

-45 232177121 6610 288 343Temp °F Temp °C

Ketron® CM CA30 PEEK Heat Deflection Temperature (HDT)

232°C /450°F Filled with 30% carbon fiber

Ketron® CM 1030HT PEK HDT 250°C / 480°F Ketron® HT resin base with 30%

carbon fiber Fills the gap between PEEK and PAI

without the chemical limitations

Duratron® T4540 PAI HDT 280°C / 534°F Higher temperature & pressures Low CLTE for improved stability Some chemical limitations

Fluorosint® 500 PTFE HDT 132°C / 270°F Synthetic mica-filled PTFE Exceptional dimensional stability Better wear characteristics than virgin PTFE

Polymer Tooth

Angled Aluminum Tooth

Straight Aluminum Tooth

Shaft OD

Clearance Same As Installed

Clearance LargerThan Installed

Clearance Larger Than Installed

Notethegallingof theshaft

Deflected Tooth Deformed Tooth Deformed Tooth

Shaft OD

Shaft OD

Typical Labyrinth Tooth Designs at Installation Installed clearance of polymer teeth is tighter than aluminum seal

Typical Labyrinth Tooth Designs at Critical SpeedsAt critical speeds, an angled polymer tooth will deflect with shaft (similar to a cantilever) where the aluminum tooth will deform or “mushroom over”

Typical Labyrinth Tooth Designs after Critical Speeds After exposure to critical speed the thermoplastic tooth will return to original shape due to the plastic “memory” of the engineering thermoplastic while the aluminum tooth remains damaged

Polymer Teeth vs Aluminum Teeth – The Benefit

Typical Polymers for Tooth on Stator Seals: Ketron® PEEK or Duratron® PAI

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Compressor seal designs - Two styles

COMPRESSORS

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ROTATING SHAFT

POLYMER

ROTATING SHAFT

ABRADEABLE SEALS

POLYMER POLYMER

Tooth on Rotor Seals require a polymer material to be “Abradable”Typical Material – Fluorosint® 500 PTFE

Tooth on StatorSeals require a polymer material to be very stable with temperatureTypical Material – Ketron® PEEK or Duratron® PAI

Tooth on Stator designTooth on Rotor design

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Tooth on Rotor Application Story:

Rotating equipment, like compressors, that have moving teeth or impeller blades benefit from shaft seals or shrouds made from abradeable materials.

Problem: Threat of metal to metal contact results in increased clearances, excessive leakage and decreasing efficiency. Also risking damage to rotors, shafts and bearings.

Solution: Fluorosint®

Abradeable polymer seal allows for rotating blades or teeth to cut into the polymer for the tightest clearance Reduced clearance = less leakage, higher efficiency Resistance to harsh chemical service = less corrosion

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APPLICATION STORIES

Tooth on Stator Application Story:

Compressors that have seals with stationary teeth require materials with extreme dimensional stability at high temperatures.

Problem: Typical Aluminum seals deform or “roll-over” during standard shaft rubs resulting in increased clearance and loss of efficiency. In addition, corrosion of metal seals can be a real problem in aggresssive gases.

Solution: Duratron® PAI or Ketron® PEEK Polymer seals are resilient eliminating tooth roll-over and comeback

preserving tight tolerances Tighter clearances are achieved at start up and maintained longer compared

to metal seals Increased efficiencies result in tremendous savings over the life

of the unit

Material Evolution:

From: Aluminum

To: Duratron® PAI Ketron® PEEK Fluorosint® PTFE

VALVES & SEALS

318

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Check Valve Open and Closed

Butterfly Valve Open and Closed

Globe Valve Open and Closed Ball Valve Open and Closed

Gate Valve Open and Closed

Centrifugal Pump

Rotary Screw Pump Rotary Screw Pump

What is a valve?

Valves regulate fluid flow by opening and closing. The moving parts of a valve and their actuators are prime opportunities to improve performance through the use of advanced engineered thermoplastics.

Valve Examples

Valve applications include bearings, seats, stem seals, and also the valve body and stem.

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3 SELECTION MATRIX VALVES

TIVAR® H.O.T. – High Operating Temperature UHMW-PE that offers performance to 275°F.

Fluorosint® 207, HPV, 500 – Mica-filled PTFE offers drastic load resistance and lower CLTE than all other filled PTFEs.

Fluorosint® MT-01 – Exotic fillers offer this PTFE based material sealing capability to 675°F.

Duratron® Family of materials offer extreme performance at temperatures from 400° to 800°F

= Standard Materials

= Additional Quadrant Materials

Pres

sure

Res

ista

nce

Temperature

150°F 65°C

250°F 121°C

350°F 176°C

450°F 232°C

550°F 288°C

LOW

HIGH

TIVAR®

UHMW-PETIVAR® H.O.T. Fluorosint®

MT-01

Fluorosint® 135, 207, HPV, 500

Ketron® CA30, GF30 PEEK, 1030HT PEK

Duratron® PAI, PI, PBI

PTFE

FilledPTFE

Ketron® PEEK, TF20 PEEK

We take the stress outAny shape converter can take a good resin and make high stress materials with poor properties. Specify the shape manufacturer and then you are specifying a process which includes consistent resin and consistent shape properties...including consistent low stress materials. Let Quadrant eliminate the guess work and provide a consistent low stress shape regardless of the resin.

CE

RTIFIED

SHAPES

OURS: LOW STRESS

THEIRS:HIGH STRESS

Seals: Are you considering all your options?

Quadrant offers many materials that fill performance gaps which can save you time and money.

Quadrant creates materials that fill performance gapsExposure to Pressure Levels and Heat

Techtron® 1000, HPV PPS

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Materials to ANSI Class Selection Tool

Quadrant has developed this tool to match materials to appropriate ANSI classes as defined in standard B16.5. This tool was developed using customer feedback and intended to help a designer select a range of materials that should satisfy most applications. It does not replace the specific design review and testing that Quadrant advocates for all applications. To select a material, use the vertical axis to choose the area under the required ANSI class, then move along the horizontal axis until the proper application temperature is found.

For example, Techtron® HPV PPS would be a good choice for a supported application that needs to meet Class 300 at an operating temperature of approximately 250°F (121°C). The matrix provided on the following page provides additional information about specific application areas.

Once you have narrowed your search, review of specific physical and chemical performance characteristics can help identify the most appropriate material for use. Physical and chemical performance data is summarized in this guide. It is also available online at www.quadrantepp.com and offered in Quadrant’s Products and Applications Guide and Quadrant’s Design and Fabrication Guide.

100°F(38°C)

200°F(93°C)

300°F(149°C)

400°F(204°C)

500°F(260°C)

600°F(315°C)

Pres

sure

Temperature

Carbon Steel

Stainless Steel

0

200

400

600

800

1000

1200

1400

1600

Techtron ® PPSFluorosint ® 135 PTFE

Techtron ® HPV PPS

Techtron ® PSBG PPS

Ketron® PEEK

Duratron® PAI

Ketron® HPV PEEK

Fluorosint ® 500 PTFE

Fluorosint ® HPV PTFE

Ketron ® CA30 PEEK




Duratron ® CU60 PBI

Ertalyte® TX PET

Acetron® GP POM-C

TIVAR® 1000 UHMW-PE

Nylatron® PA

[KPA]11,032

9,653

8,274

6,895

5,516

4,137

2,758

1,379

[PSIG]

CLASS 600

CLASS 300

CLASS 150

Recommended Temperature Ranges Based on Material’s HDT*

Valve Component

ANSI B16.5Valve

Standard

Up to 200°F(Up to 93°C)

200°F - 300°F(93°C - 149°C)

300°F - 400°F(149°C - 204°C)

400°F - 500°F(204°C - 260°C)

Above 500°F(Above 260°C)

ANSI B16.5Valve

Standard

Body

Class 150Nylatron® GSM PA6

Acetron® GP POM-C

Techtron® PPS

Techtron®

HPV PPS

Techtron®

PSBG PPS

Ketron®

CA30 PEEKDuratron®

CU60 PBI

Class 150

Class 300 Class 300

Class 600 Class 600

STEM

Class 150

Acetron®

GP POM-CErtalyte®

TX PET-P

Techtron®

HPV PPS

Techtron®

PSBG PPS

Ketron®

HPV PEEK

Duratron®

T4301 PAI

Duratron®

T4540 PAI

NA

Class 150

Class 300 Class 300

Class 600 Class 600

ThrustBearing

Class 150 TIVAR® 1000UHMW-PE Techtron®

HPV PPS

Techtron®

PSBG PPS

Techtron®

HPV PPS

Techtron®

PSBG PPS

Fluorosint®

500 PTFE

Fluorosint®

HPV PTFE

Duratron®

T4540 PAI

Ketron®

HPV PEEK

Class 150

Class 300 Acetron®

GP POM-C

Ertalyte® TX PET

Class 300

Class 600 NA Class 600

Soft Seat(Low Pressure)Same for HardSeat Inserts

Class 150 TIVAR® 1000UHMW-PE

Fluorosint® 207PTFE

Fluorosint® 207PTFE Fluorosint®

500 PTFE

Fluorosint®

HPV PTFE

Fluorosint®

MT-01

Class 150

Class 300 Acetron®

GP POM-C

Ertalyte® TX PET

Fluorosint®

500 PTFE

Fluorosint®

HPV PTFE

Class 300


Hard Seat(High Pressure)Same for HardSeat Inserts

Class 150Acetron®

GP POM-C

Ertalyte® TX PET

Techtron®

PPSKetron®

1000 PEEK

Ketron®

HPV PEEK

Duratron®

T4301 PAI

Duratron®

T4540 PAI

Ketron®

HPV PEEK

Duratron®

T4540 PAI

Class 150

Class 300 Class 300

Class 600 Duratron®

CU60 PBI Class 600

STEM SealAdapters

(Male & Female)

Class 150Acetron®

GP POM-C

Ertalyte® TX PET

Techtron®

HPV PPS

Techtron®

PSBG PPS

Techtron®

HPV PPS

Techtron®

PSBG PPS

Ketron®

1000 PEEK

Ketron®

HPV PEEK

Duratron®

T4301 PAI

Duratron®

T4540 PAI

Ketron®

CA30 PEEK

Duratron®

T4203 PAI

Class 150

Class 300 Class 300


STEMPrimarySeals

Class 150

Fluorosint®

207 PTFEFluorosint®

207 PTFE

Fluorosint® 207PTFE Fluorosint®

500 PTFE

Fluorosint®

HPV PTFE

Fluorosint®

MT-01

Class 150

Class 300Fluorosint®

500 PTFE

Fluorosint®

HPV PTFE

Class 300

Class 600 Class 600

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3VALVES & SEALS

This matrix uses the same customer experiences to group materials by ANSI class – with the added dimension of application area. Select the appropriate application, ANSI class and temperature range to narrow your materials search. More questions? Contact our Technical Support Team at 800-366-0300 for additional input.

*Quadrant considers HDT, or Heat Deflection Temperature @ 264 psi/1820 kpa (ASTM D648) as typically the best way to compare materials for applications under load. Some supplier data unfortunately reflects only Continuous Use Temperature (CUT). This can be very close to the melting point. It is mainly meant to indicate loss of toughness from temperature exposure over time for electrical enclosures. Our data tables typically show both values when they are available.

100°F(38°C)

200°F(93°C)

300°F(149°C)

400°F(204°C)

500°F(260°C)

600°F(315°C)

Pres

sure

Temperature

Carbon Steel

Stainless Steel

0

200

400

600

800

1000

1200

1400

1600

Techtron ® PPSFluorosint ® 135 PTFE

Techtron ® HPV PPS

Techtron ® PSBG PPS

Ketron® PEEK

Duratron® PAI

Ketron® HPV PEEK



Ketron ® CA30 PEEK




Duratron ® CU60 PBI

Ertalyte® TX PET

Acetron® GP POM-C

TIVAR® 1000 UHMW-PE

Nylatron® PA

[KPA]11,032

9,653

8,274

6,895

5,516

4,137

2,758

1,379

[PSIG]

CLASS 600

CLASS 300

CLASS 150

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WHY QUADRANT?THE PROOF IS IN THE DATA

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Ketron® 1000 PEEK EXT

Ketron® 1000 PEEK IM

Ketron® 1000 PEEK SP

Ketron® CA30 PEEK

Unfilled PEEK in extruded plate, rod & tube. Offers highest elongation of all PEEK grades. Ideal for large cross section tube in small quantities.

Unfilled PEEK in injection molded tubes. Higher internal stress than extruded or compression molded. Excellent combination of thermal resistance and high compressive strength.

Unfilled PEEK in compression molded rings.

30% carbon fiber filled PEEK in extruded plate, rod & tube. More thermal conductivity than unreinforced PEEK with enhanced compressive strength and stiffness.

Extruded

Injection Molded

CompressionMolded

Extruded

480ºF

250ºC

480ºF

250ºC

480ºF

250ºC

480ºF

250ºC

Material Advantages

CERTIFIED

SHAPES

CERTIFIED

SHAPES

CERTIFIED

SHAPES

CERTIFIED

SHAPES

MaterialsProcessMethod

NORSOK M-710Approved

MAX Operating Temperature

Other materials available, contact a quadrant material specialist at 800-366-0300.

Ketron® PEEK?

The industry’s first NORSOK M-710 certified stock shapes for oil, gas and petrochemical applications.

Quadrant was the world’s FIRST stock shape manufacturer to earn NORSOK M-710 compliance and provides the most accurate and reliable data on their stock shapes. The NORSOK M-710 specification was developed by the Norwegian petroleum industry to ensure sufficient understanding and experience of oil and gas materials. It specifies a test procedure to predict the progressive degradation of thermoplastic materials exposed to a sour fluid at elevated pressure and temperature over an extended period of time. NORSOK M-710 defines the requirements for critical non-metallic (polymer) sealing, seat and back-up materials and components for permanent use subsea, including well completion, christmas trees, control systems & valves, and topside valves in critical gas systems.

26

Ketron® PEEK

Welding of segments into large OD rings consisting of 4,6, or 8 segments depending on OD ring size & plate availability

Available in all PEEK formulations plus additionalmaterials under developement

OD Range: min 700mm – max 3m Cross Section: 100 x 100mm max, typically range 25 x 50mm

Industries: oil & gas, aerospace, industrial, military equipmentLarge dia. high temperature/high pressure seals, BU rings, guide rings

Dedicated high temperature mirror welding system, fully computercontrolled welding system (temp, forces, displacements)

WOW!3 M DIAMETER

Ketron® CM PEEKCompression Molded Moderate to heavy wall Very low internal stress Low production minimum

Ketron® EX PEEKExtruded Moderate wall Low, symmetrical internal stress Long lengths available (up to 3M)

Ketron® IM PEEKInjection Molded Thin wall (<.500”) Higher internal stress Stocked in limited sizes

Compression Molded

1.0” (25.5mm)

Tube Outside Diameter (OD)Tu

be In

side

Dia

met

er (I

D)

40” (1016mm)14” (355.6mm)10” (254mm)9.

5” (2

41m

m)

11.5

” (2

92m

m)

35”

(889

mm

)

Extruded Injection Molded

Low Stress Stock Shapes available in all sizes

Segmented Welded Rings

NEW

27

PROPER MATERIAL SPECIFICATIONS

Injection

Extruded

Compression Molded

500

45035025015050-50

1000

1500

2000

2500

3000

3500

Same resin processed 3 different ways

Injection Extrusion Compression

Significant fiber alignment Some fiber alignment 100% Random fiber alignment

Quadrant’s shape data approach?

You see, most plastic shape converters don’t have the resources to test and provide accurate data on the finished stock shapes you’re buying so they just pass on the raw material resin datasheet from their suppliers – this is termed “Data Dumping.” Besides hiding poor quality material results prone to critical part failure and machining issues, this tactic ignores the natural influence processing methods (Injection, Extrusion, Compression) have on a shape’s properties. Stopping the industry’s acceptance of mis-leading data reporting begins by demanding post-process Shape Data and is exactly why Quadrant developed The Shape Data ApproachTM to make it easy for customers to ensure they’re getting quality materials that are consistently on spec.

Polymer & fiber alignment differ by process

Fiber alignment differs by conversion process and part geometry. The result can be a significant difference in mechanical properties. Calling out the appropriate conversion process in your material specification is critical to ensure you get the properties and the correct material you need.

Process Matters. When writing a material

specification, call out the manufacturing process.

kpsimpa24,13

20,68

17,24

13,79

10,34

6,89

3,45

550(ºF)(ºC) -45 10 66 121 177 232 288

28

PROPER MATERIAL SPECIFICATIONS

Injection Molded Extruded Compression Molded

A hyper fast, high pressure process that freezes the shape into a dramatically lower temperature tool cavity cooling at a very fast rate.

Significant directionality of fibers Highest level of internal stress Resin manufacturer’s use for their data

A slow, mechanical process where polymer is pushed through a die at a slow rate of speed cooling at a fairly slow and controlled rate.

Some directionality of fibers Lower internal stress compared to injection

molding

Process of squeezing polymer under pressure and temperature in a controlled and uniform manner with no die and no nozzle.

Zero directionality of fibers Lowest level of internal stress

Stock shape & finished components

Use it when: Part volumes are high Higher stresses are tolerable

Stock shape

Use it when: Part volumes are medium Longer machining stock offers a

yield advantage Symmetrical, consistant stress is

preferred

Stock shape

Use it when: Part volumes are low Very large parts are required The lowest internal stress

is mandated

Property Test Method Ketron® 1000 IM

Ketron® 1000 EX

Resin DataKetron® GF30 IM

Ketron® GF30 EX

Ketron® GF30 CM

Resin Data*

Mechanical

Ultimate Tensile Strength @ 73°F, psi ASTM D 638 16,000 16,000 14,100 14,000 14,000 7,400 22,000

Tensile Modulus @ 73°F, psi ASTM D 638 600,000 630,000 508,000 900,000 1,000,000 850,000 1,500,000

Elongation, at break @ 73°F, % ASTM D 638 40 40 60 9 2 1 7

Flexural Strength @ 73°F, psi ASTM D 790 23,000 25,000 24,700 20,000 23,000 12,000 37,900

Flexural Modulus of Elasticity @ 73°F, psi ASTM D 790 600,000 600,000 595,000 920,000 1,000,000 900,000 1,510,000

Compressive Strength @ 73°F, psi ASTM D 695 20,000 20,000 17,100 21,000 22,000 19,000 24,500

Compressive Modulus @ 73°F, psi ASTM D 695 425,000 500,000 500,000 550,000 500,000

Virgin PEEK 30% Glass Filled PEEK

* Misleading, higher mechanical properties are the result of fiber alignment in injection molded test plaques.

Plastic conversion processes and their effect on fiber alignment

Data by process

Resin manufacturers injection mold test samples. Resin data is often misleadingly higher than expected.

29

MATERIAL COMPABILITY

200

400

600

800

1000

1200

1400

1,379

2,758

4,137

5,518

8,274

9, 653

1600 11,032

0

MOD

ULUS

TEMPERATURE

45035025015050-50 550 650 750

Ketron® CA30 PEEK (extruded)

Ketron® CM 1030HT PEK


Temp °F

kpsi mpa

6,895

Ketron® HPV PEEK (extruded)

Ketron® 1000 PEEK (extruded)

Fluorosint® HPV

-45Temp °C 232177121 6610 288 343 399

0

CLTE

: i

n/in

/°F

x 10

-5

TEMPERATURE

30025020015010050 350 400 450 500 Temp °F

IN

5

7

8

6

3

2

1

4

Ketron® 1000 PEEK (extruded)

Ketron® CM 1030HT PEK


Fluorosint® 500

Ketron® CA30 PEEK (extruded)

Aluminum

Coefficient of Linear Thermal Expansion, or CLTE, describes how the size of a part will change with changes in temperature. The smaller the material’s CLTE, the more dimensionally stable a part made from that material will be as the temperatures are varied. CLTE values are very important and must be accounted for in close tolerance applications such as compressor labyrinth seals, pump case wear rings, pump shaft and throat bushings.

Dynamic Mechanical Analysis, or DMA, indicates polymer stiffness at elevated temperature. These data are more relevant for engineering calculations than HDT as HDT is an instantaneous test. DMA parallels actual polymer modulus decay as the temperature is gradually increased resembling an actual operating condition. These data are useful in determining the polymer seal stiffness at operating temperatures, and the seal maximum service temperature.

Tensile Modulus vs. Temperature

CLTE (Coefficient of Linear Thermal Expansion)

*ENGINEERING NOTE: Like all PTFE-based shapes, Fluorosint® 500 PTFE exhibits a transition zone phenomena from 50°F (10°C) to 77°F (25°C). This phenomena and its associated change in volume needs to be taken into account when designing Fluorosint 500 PTFE seals. Contact Quadrant’s Technical Team at 800-366-0300, or online at quadrantepp.com for assistance with your design.

MPa

10 38 66 93 121 149 177 204 232 260 Temp ºC

mm 20,32

17,78

15,24

12,7

10,61

7,62

5,08

2,54

0

CLTE

: in/

in/º

F /

m/m

/ºC

x 10

-5

Chemical Service Temp ˚F Temp ˚C Pressure (psi/kpa) DurationDuratron®

PAIKetron®

PEEKTechtron®

PPSFluorosint®

PTFE

Air Refinery 200 to 600 93 to 3151,000 to 5,000 psi

6,894 to 34,473 kpa NA A to 500˚FA to 260˚C

A to 500˚FA to 260˚C



Ammonia Fertilizer–Refinery 350 to 400 177 to 2042,000 to 5,000 psi

13,789 to 34,473 kpa Min 24 hrs, 30 days C A A B

Ammonia Syn Gas Fertilizer–Refinery 350 to 400 177 to 2042,000 to 5,000 psi

13,789 to 34,473 kpa Min 24 hrs, 30 days C A A B

Chlorine Chlorine Operations 250 121250 psi

1,724 kpa 35 days C C C A

Ethylene Gas Ethylene–Olefin Manuf 250 1211,000 to 7,000 psi

6,894 to 48,263 kpa Min 1 week, 30 days A A A A

Propylene Refrigeration Ops -250 -1571,000 to 7,000psi


Methane Refinery, LNG 200 931,000 to 7,000 psi


Propane Refinery, LNG 200 931,000 to 7,000 psi


H2S Downhole Drilling 250 to 550 121 to 2881,000 to 15,000 psi

6,894 to 10,3421 kpa Min 1 week, 30 days B A A A

CO2 Downhole Drilling 250 to 550 121 to 2881,000 to 15,000 psi


Brine Downhole Drilling 250 to 550 121 to 2881,000 to 15,000 psi

6,894 to 10,3421 kpa Min 1 week, 30 days B A A A

Steam All Services 300 to 650 149 to 3431,000 to 15,000 psi

6,894 to 10,3421 kpa Min 1 week, 30 daysB to 300 ˚F A A AB to 149 ˚C A A A

Hydrocarbons

Benzene

Butane

Diesel Oil

Crude Oil

Gasoline

Kerosene

Tolune

Xylene

Cyclohexane

Naphta

All Services -250 to 550 -157 to 2881,000 to 15,000 psi

6,894 to 10,3421 kpaMin 1 week, 30 days

A A A B

A A A AA A A AA A A AA A A BA A A AA A A BA A A BA A A AA A A A

LNG Pipeline, LNG Plant -250 to 550 -157 to 2881,000 to 7,000 psi


AminesCorrosion Protection

NACE A & NACE B-250 to 400 NACE A & B

-157 to 204 NACE A & B

1,000 to 7,000 psi6,894 to 48,263 kpa Min 1 week, 30 days

CA

AA

AA

AA

Refrigerants R134A, R22 R134A, R22 R134A, R22500 to 1,500 psi


30

MATERIAL COMPABILITY

Ratings: A B CA (Acceptable): No Attack, Little or No AbsorptionB (Caution): Slight Attack, Satisfactory Use for the ChemicalC (Unacceptable): Severe Attack, Product Should Not Be Used for This Service Ratings

*Chemical resistance data is based on practical application experience and the user is expected to test materials for their suitability in all environments and conditions.

Oil, Gas & petroChemical Processing & Applications - Chemical Resistance Data

31

Product Description

Units

Test

Method

ASTM

TIVAR®

HPVUHMW-PE

TIVAR®

H.O.TUHMW-PE

TIVAR®

1000Nylatron®

MC901 PA6Acetron®

GP POM-CErtalyte®

TX PET-PFluorosint®

135Fluorosint®


MT-01Fluorosint®

207Techtron®

HPV PPSKetron®

1000 PEEKKetron®

GF30Ketron®

HPV PEEK

Ketron®

CM HPVPEEK

Ketron®

CM CA30PEEK

Ketron®

CM 1030HTPEK

Duratron®

T4301 PAIDuratron®

T4501 PAIDuratron®

T4540 PAIDuratron®

T7130 PAIDuratron®

T7530 PAIDuratron®

CU60 PBI

UHMW-PEHigh TempUHMW-PE

UHMW-PEBlue, HeatStabilized

PA6

PremiumPorosity-

freePOM-C

Premium,Solid

LubricantFilled PET

Propietary Filled PTFE

Mica FilledPTFE

Carbon Fiber &

PropietaryFilled PTFE

Mica Filled PTFE

Premium,Solid

LubricantFilled PPS

UnfilledPEEK

30% Glass Fiber

Filled PEEK

Premium,Solid Lub.

Filled PEEK

BearingGradePEEK

30% Carbon

Fiber FilledPEEK

30% CarbonFilled

PEK HT

BearingGrade PAI

BearingGrade PAI

BearingGrade PAI

30% CarbonFilledPAI

30% CarbonFilledPAI

UnfilledPBI

CompressionMolded

CompressionMolded

CompressionMolded Cast Extruded Extruded Compression

MoldedCompression

MoldedCompression

MoldedCompression

Molded ExtrudedInjection Molded

Extruded Extruded Extruded CompressionMolded

CompressionMolded

CompressionMolded Extruded Compression

MoldedCompression

Molded Extruded CompressionMolded

CompressionMolded

1 Specific Gravity 73°F - D792 0.93 0.94 0.93 1.15 1.41 1.44 1.91 2.32 2.27 2.3 1.43 1.31 1,51 1.44 1.44 1.42 1.43 1.45 1.45 1.46 1.47 1.51 1.3

2 Tensile Strength 73°F psi D638 5,900 6,800 5,800 12,000 9,500 10,500 1,300 1,100 2,100 1,500 10,900 16,000 14,000 11,000 7,900 16,000 16,000 15,000 9,000 13,000 22,000 12,500 16,000

3 Tensile Modulus of Elasticity 73°F psi D638 56,000 72,500 80,000 400,000 400,000 500,000 370,000 300,000 326,000 250,000 540,000 630,000 1,000,000 850,000 530,000 1,400,000 1,350,000 900,000 500,000 575,000 1,200,000 730,000 850,000

4 Tensile Elongation (at break) 73°F % D638 390 300 300 20 30 5 3 30 40 50 4 40 2 2 2 3 3 3 3 3 2.5 2.6 2

5 Flexural Strength, 73°F psi D790 3,000 3,800 3,500 16,000 12,000 14,000 2,500 2,200 4,000 2,000 10,500 25,000 23,000 27,500 13,000 23,000 22,000 23,000 12,000 12,000 - 18,000 32,000

6 Flexural Modulus of Elasticity 73°F psi D790 77,000 80,000 87,000 500,000 400,000 360,000 300,000 500,000 485,000 350,000 535,000 600,000 1,000,000 1,100,000 700,000 1,000,000 1,150,000 800,000 550,000 550,000 - 1,000,000 950,000

7 Shear Strength 73°F psi D732 4,800 4,800 4,800 11,000 8,000 8,500 2,500 2,100 2,600 1,700 - 13,000 14,000 10,000 - 11,000 - 16,400 - - - - -

8 Compressive Strength, 10% Deformation 73°F psi D695 3,000 3,000 3,000 15,000 13,500 15,250 7,000 4,000 3,400 3,800 15,500 20,000 22,000 20,000 20,000 28,000 29,000 22,000 20,000 20,000 37,000 43,000 50,000

9 Compressive Modulus of Elasticity 73°F psi D695 76,000 80,000 80,000 400,000 260,000 400,000 200,000 250,000 250,000 225,000 342,000 500,000 550,000 500,000 400,000 580,000 525,000 950,000 375,000 350,000 1,000,000 971,000 900,000

10 Hardness, Rockwell, Scale as noted 73°F - D785 R56 N/A R56 M85 (R115) M88 (R120) M94 R80 R55 R74 R50 M84 M100 M126 (R126) M85 - M108 (R125) M108 (R125) E70 (M106) E70 (M106) E66 (M107) E91 E90 E105 (M125)

11 Hardness, Durometer, Shore “D” Scale 73°F - D2240 D65 D68 D66 D85 D85 D80 D74 D70 - D65 - D85 D89 - - D91 D91 D90 D90 D90 - - D94

12 Izod Impact (notched), 73°F ft.lb./in.of notch D256 Type “A” No Break No Break No Break 0.4 1 0.4 0.5 0.9 - 1.0 1.4 0.6 0.8 0.7 1.0 1.4 1.0 0.8 0.5 1.1 0.9 0.7 0.5

13 Coefficient of Friction (Dry vs. Steel) Dynamic - QTM 55007 0.09 0.12 0.12 0.2 0.25 0.19 0.15 0.15 0.18 0.10 0.2 0.32 - 0.21 0.20 0.24 0.24 0.2 0.2 0.2 0.30 0.22 0.24

14 Limiting PV (with 4:1 safety factor applied) ft. lbs./in.2 min QTM 55007 6,000 3,000 3,000 3,000 2,700 6,000 14,300 8,000 4,500 8,000 8,750 8,500 - 20,000 35,000 17,000 15,000 7,500/ 40,000* 22,500 7,500 14,000 43,000 37,500

15 Wear Factor “k” x 10 -10 in.3-min/ft.lbs. hr QTM 55010 20 - 10 100 200 35 32 600 200 85 62 375 - 100 130 102 85 300/10* 150 315 75 112 60

16 Coefficient of Linear Thermal Expansion (-40°F to 300°F) in./in./°F E-831 (TMA) 8.0 x 10 -5 11.0 x 10 -5 1.1 x 10 -4 5.0 x 10 -5 5.4 x 10 -5 4.5 x 10 -5 2.5 x 10-5 2.5 x 10 -5 3 x 10 -5 5.7 x 10 -5 3.3 x 10 -5 2.6 x 10 -5 1.2 x 10 -5 1.7 x 10-5 2.7 x 10 -5 2.3 x 10 -5 2.1 x 10 -5 1.4 x 10 -5 2 x 10 -5 2 x 10 -5 0.5 x 10 -5 0.5 x 10 -5 1.3 x 10 -5

17 Heat Deflection Temperature 264 psi °F D648 116 116 116 200 220 180 220 270 200 210 240 320 450 383 480 450 480 534 534 534 540 540 800 (DMA)

18 Tg-Glass transition (amorphous) °F D3418 N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A 527 527 527 527 527 750 (DMA)

19 Melting Point (crystalline) peak °F D3418 275 275 275 420 335 491 621 621 - 621 536 644 644 644 644 644 650 N/A N/A N/A N/A N/A N/A

20 Continuous Service Temperature in Air (Max.) (1) °F - 180 275 180 260 180 210 500 500 600 500 430 480 480 482 480 480 480 500 500 500 500 500 600

21 Thermal Conductivity BTU in./hr. ft.2 °F F433 2.84 2.84 2.84 2.37 1.6 1.9 - 5.3 - 3.05 2.1 1.75 2.98 1.7 - 6.37 6.3 3.7 3.7 2.81 0 0 2.8

22 Dielectric Strength, Short Term Volts/mil D149 - - 1,150 500 420 533 - 275 - 200 500 480 500 - - - - - - - - 550

23 Surface Resistivity ohm/square EOS/ESD S11.11 >1015 >1015 >1015 >1013 >1013 >1013 >105 >1013 <106 >1013 >1013 >1013 >1013 <1013 <1013 <105 <105 >1013 >1013 >1013 - - >1013

24 Dielectric Constant, 10 6 Hz - D150 - 2.3 2.3 3.7 3.8 3.6 - 2.85 - 2.65 - 3.3 - - - - - 5.4 5.4 - - - 3.2

25 Dissipation Factor, 10 6 Hz - D150 - 5 x 10-4 - - 0.005 .02 - 0.008 - 0.008 - 0.003 - - - - - 0.037 0.042 - - - 0.003

26 Flammability @ (1⁄8 in.) (5) - UL 94 HB HB HB HB HB HB V-0 V-0 V-0 V-0 V-0 V-0 V-0 V-0 - V-0 V-0 V-0 V-0 V-0 V-0 V-0 V-0

27 Water Absorption Immersion, 24 Hours % by wt. D570 (2) <0.01 <0.01 <0.01 0.6 0.2 0.06 0.1 0.1 0.1 0.03 0.01 0.1 0.1 0.05 0.07 0.15 0.15 0.4 0.3 0 .3 0.3 0.4

28 Water Absorption Immersion, Saturation % by wt. D570 (2) <0.01 <0.01 <0.01 7 0.9 0.47 0.3 0.3 - 0.20 0.09 0.5 0.3 0.3 - 0.5 0.50 1.5 1.5 1.5 1.5 1.5 5

29 Acids, Weak, acetic, dilute hydrochloric or sulfuric acid @73°F A A A L L A A A A A A A A A A A A A A A A A L

30 Acids, Strong, conc. hydrochloric or sulfuric acid @73°F A A A U U L A A A A L L L L L L L L L L L L U

31 Alkalies, Weak, dilute ammonia or sodium hydroxide @73°F A A A L A A A A A A A A A A A A A L L L L L L

32 Alkalies, Strong, strong ammonia or sodium hydroxide @73°F A A A U U U U U U U A A A A A A A U U U U U U

33 Hydrocarbons–Aromatic, benzene, toluene @73°F L L L A A A A A A A A A A A A A A A A A A A A

34 Hydrocarbons–Aliphatic, gasoline, hexane, grease @73°F A A A A A A A A A A A A A A A A A A A A A A A

35 Ketones, Esters, acetone, methyl ethyl ketone @73°F A A A A A A A A A A A A A A A A A A A A A A A

36 Ethers, diethyl ether, tetrahydrofuran @73°F L L L A A A A A A A A A A A A A A A A A A A A

37 Chlorinated Solvents, methylene chloride, chloroform @73°F L L L L L U A A A A A A A A A A A A A A A A A

38 Alcohols, methanol, ethanol, anti-freeze @73°F A A A L A A A A A A A A A A A A A A A A A A A

39 Continuous Sunlight @73°F L L L L L L A A A A L L L A A A A A A A A A L

40 Relative Cost (4) $ $ $ $$ $$ $$+ $$$ $$$$ $$$$$ $$$$ $$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$$ $$$$$ $$$$$

41 Relative Machinability (1-10, 1 = Easier to Machine) 2 2 2 1 1 2 2 2 5 2 3 5 7 7 5 7 8 5 6 6 8 8 10

NOTE: Property data shown are typical average values. A dash (-) indicates insufficient data available for publishing.

MEC

HANI

CAL

THE

RMAL

ELEC

TRIC

ALCH

EMIC

ALOT

HER

A = Acceptable Service

L = Limited Service

U = Unacceptable

QTM = Quadrant Test Method

KEY

32

IMPERIAL DATA

Product Description

Units

Test

Method

ASTM

TIVAR®

HPVUHMW-PE

TIVAR®

H.O.TUHMW-PE

TIVAR®

1000Nylatron®

MC901 PA6Acetron®

GP POM-CErtalyte®


135Fluorosint®


MT-01Fluorosint®

207Techtron®

HPV PPSKetron®

1000 PEEKKetron®

GF30Ketron®

HPV PEEK

Ketron®

CM HPVPEEK

Ketron®

CM CA30PEEK

Ketron®

CM 1030HTPEK

Duratron®

T4301 PAIDuratron®

T4501 PAIDuratron®

T4540 PAIDuratron®

T7130 PAIDuratron®

T7530 PAIDuratron®

CU60 PBI



PA6

PremiumPorosity-

freePOM-C

Premium,Solid

LubricantFilled PET


Mica FilledPTFE

Carbon Fiber &


Mica Filled PTFE

Premium,Solid

LubricantFilled PPS

UnfilledPEEK

30% Glass Fiber

Filled PEEK

Premium,Solid Lub.

Filled PEEK

BearingGradePEEK

30% Carbon

Fiber FilledPEEK

30% CarbonFilled

PEK HT

BearingGrade PAI

BearingGrade PAI

BearingGrade PAI

30% CarbonFilledPAI

30% CarbonFilledPAI

UnfilledPBI

CompressionMolded

CompressionMolded


MoldedCompression

MoldedCompression

MoldedCompression



CompressionMolded


MoldedCompression


CompressionMolded


2 Tensile Strength 73°F psi D638 5,900 6,800 5,800 12,000 9,500 10,500 1,300 1,100 2,100 1,500 10,900 16,000 14,000 11,000 7,900 16,000 16,000 15,000 9,000 13,000 22,000 12,500 16,000

3 Tensile Modulus of Elasticity 73°F psi D638 56,000 72,500 80,000 400,000 400,000 500,000 370,000 300,000 326,000 250,000 540,000 630,000 1,000,000 850,000 530,000 1,400,000 1,350,000 900,000 500,000 575,000 1,200,000 730,000 850,000


5 Flexural Strength, 73°F psi D790 3,000 3,800 3,500 16,000 12,000 14,000 2,500 2,200 4,000 2,000 10,500 25,000 23,000 27,500 13,000 23,000 22,000 23,000 12,000 12,000 - 18,000 32,000

6 Flexural Modulus of Elasticity 73°F psi D790 77,000 80,000 87,000 500,000 400,000 360,000 300,000 500,000 485,000 350,000 535,000 600,000 1,000,000 1,100,000 700,000 1,000,000 1,150,000 800,000 550,000 550,000 - 1,000,000 950,000

7 Shear Strength 73°F psi D732 4,800 4,800 4,800 11,000 8,000 8,500 2,500 2,100 2,600 1,700 - 13,000 14,000 10,000 - 11,000 - 16,400 - - - - -

8 Compressive Strength, 10% Deformation 73°F psi D695 3,000 3,000 3,000 15,000 13,500 15,250 7,000 4,000 3,400 3,800 15,500 20,000 22,000 20,000 20,000 28,000 29,000 22,000 20,000 20,000 37,000 43,000 50,000

9 Compressive Modulus of Elasticity 73°F psi D695 76,000 80,000 80,000 400,000 260,000 400,000 200,000 250,000 250,000 225,000 342,000 500,000 550,000 500,000 400,000 580,000 525,000 950,000 375,000 350,000 1,000,000 971,000 900,000



12 Izod Impact (notched), 73°F ft.lb./in.of notch D256 Type “A” No Break No Break No Break 0.4 1 0.4 0.5 0.9 - 1.0 1.4 0.6 0.8 0.7 1.0 1.4 1.0 0.8 0.5 1.1 0.9 0.7 0.5


14 Limiting PV (with 4:1 safety factor applied) ft. lbs./in.2 min QTM 55007 6,000 3,000 3,000 3,000 2,700 6,000 14,300 8,000 4,500 8,000 8,750 8,500 - 20,000 35,000 17,000 15,000 7,500/ 40,000* 22,500 7,500 14,000 43,000 37,500

15 Wear Factor “k” x 10 -10 in.3-min/ft.lbs. hr QTM 55010 20 - 10 100 200 35 32 600 200 85 62 375 - 100 130 102 85 300/10* 150 315 75 112 60

16 Coefficient of Linear Thermal Expansion (-40°F to 300°F) in./in./°F E-831 (TMA) 8.0 x 10 -5 11.0 x 10 -5 1.1 x 10 -4 5.0 x 10 -5 5.4 x 10 -5 4.5 x 10 -5 2.5 x 10-5 2.5 x 10 -5 3 x 10 -5 5.7 x 10 -5 3.3 x 10 -5 2.6 x 10 -5 1.2 x 10 -5 1.7 x 10-5 2.7 x 10 -5 2.3 x 10 -5 2.1 x 10 -5 1.4 x 10 -5 2 x 10 -5 2 x 10 -5 0.5 x 10 -5 0.5 x 10 -5 1.3 x 10 -5

17 Heat Deflection Temperature 264 psi °F D648 116 116 116 200 220 180 220 270 200 210 240 320 450 383 480 450 480 534 534 534 540 540 800 (DMA)

18 Tg-Glass transition (amorphous) °F D3418 N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A 527 527 527 527 527 750 (DMA)

19 Melting Point (crystalline) peak °F D3418 275 275 275 420 335 491 621 621 - 621 536 644 644 644 644 644 650 N/A N/A N/A N/A N/A N/A

20 Continuous Service Temperature in Air (Max.) (1) °F - 180 275 180 260 180 210 500 500 600 500 430 480 480 482 480 480 480 500 500 500 500 500 600

21 Thermal Conductivity BTU in./hr. ft.2 °F F433 2.84 2.84 2.84 2.37 1.6 1.9 - 5.3 - 3.05 2.1 1.75 2.98 1.7 - 6.37 6.3 3.7 3.7 2.81 0 0 2.8

22 Dielectric Strength, Short Term Volts/mil D149 - - 1,150 500 420 533 - 275 - 200 500 480 500 - - - - - - - - 550

23 Surface Resistivity ohm/square EOS/ESD S11.11 >1015 >1015 >1015 >1013 >1013 >1013 >105 >1013 <106 >1013 >1013 >1013 >1013 <1013 <1013 <105 <105 >1013 >1013 >1013 - - >1013


25 Dissipation Factor, 10 6 Hz - D150 - 5 x 10-4 - - 0.005 .02 - 0.008 - 0.008 - 0.003 - - - - - 0.037 0.042 - - - 0.003

26 Flammability @ (1⁄8 in.) (5) - UL 94 HB HB HB HB HB HB V-0 V-0 V-0 V-0 V-0 V-0 V-0 V-0 - V-0 V-0 V-0 V-0 V-0 V-0 V-0 V-0

27 Water Absorption Immersion, 24 Hours % by wt. D570 (2) <0.01 <0.01 <0.01 0.6 0.2 0.06 0.1 0.1 0.1 0.03 0.01 0.1 0.1 0.05 0.07 0.15 0.15 0.4 0.3 0 .3 0.3 0.4


29 Acids, Weak, acetic, dilute hydrochloric or sulfuric acid @73°F A A A L L A A A A A A A A A A A A A A A A A L

30 Acids, Strong, conc. hydrochloric or sulfuric acid @73°F A A A U U L A A A A L L L L L L L L L L L L U

31 Alkalies, Weak, dilute ammonia or sodium hydroxide @73°F A A A L A A A A A A A A A A A A A L L L L L L

32 Alkalies, Strong, strong ammonia or sodium hydroxide @73°F A A A U U U U U U U A A A A A A A U U U U U U

33 Hydrocarbons–Aromatic, benzene, toluene @73°F L L L A A A A A A A A A A A A A A A A A A A A

34 Hydrocarbons–Aliphatic, gasoline, hexane, grease @73°F A A A A A A A A A A A A A A A A A A A A A A A

35 Ketones, Esters, acetone, methyl ethyl ketone @73°F A A A A A A A A A A A A A A A A A A A A A A A

36 Ethers, diethyl ether, tetrahydrofuran @73°F L L L A A A A A A A A A A A A A A A A A A A A

37 Chlorinated Solvents, methylene chloride, chloroform @73°F L L L L L U A A A A A A A A A A A A A A A A A

38 Alcohols, methanol, ethanol, anti-freeze @73°F A A A L A A A A A A A A A A A A A A A A A A A

39 Continuous Sunlight @73°F L L L L L L A A A A L L L A A A A A A A A A L

40 Relative Cost (4) $ $ $ $$ $$ $$+ $$$ $$$$ $$$$$ $$$$ $$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$$ $$$$$ $$$$$

41 Relative Machinability (1-10, 1 = Easier to Machine) 2 2 2 1 1 2 2 2 5 2 3 5 7 7 5 7 8 5 6 6 8 8 10

* Extruded PAI materials can benefit from a post-machine cure cycle.

(1) Data represent Quadrant’s estimated maximum long-term service temperature based on practical field experience.(2) Specimens 1/8” thick x 2” diameter or square.(3) Chemical resistance data are for little or no applied stress. Increased stress, especially localized, may result in more severe attack. Examples of common chemicals also included.

(4) Relative cost of material profiled in this brochure ($ = Least Expensive and $$$$$$ = Most Expensive)(5) Estimated rating based on available data. The UL 94 Test is a laboratory test and does not relate to actual fire hazard. Contact Quadrant for specific UL “Yellow Card” recognition number.

33

Product Description

Units

Test

Method

ASTM

TIVAR®

HPVUHMW-PE

TIVAR®

H.O.TUHMW-PE

TIVAR®

1000Nylatron®

MC901 PA6Acetron®

GP POM-CErtalyte®


135Fluorosint®


MT-01Fluorosint®

207Techtron®

HPV PPSKetron®

1000 PEEKKetron®

GF30Ketron®

HPV PEEK

Ketron®

CM HPVPEEK

Ketron®

CM CA30PEEK

Ketron®

CM 1030HTPEK

Duratron®

T4301 PAIDuratron®

T4501 PAIDuratron®

T4540 PAIDuratron®

T7130 PAIDuratron®

T7530 PAIDuratron®

CU60 PBI



PA6

PremiumPorosity-

freePOM-C

Premium,Solid

LubricantFilled PET


Mica FilledPTFE

Carbon Fiber &


Mica Filled PTFE

Premium,Solid

LubricantFilled PPS

UnfilledPEEK

30% Glass Fiber

Filled PEEK

Premium,Solid Lub.

Filled PEEK

BearingGradePEEK

30% Carbon

Fiber FilledPEEK

30% CarbonFilled

PEK HT

BearingGrade PAI

BearingGrade PAI

BearingGrade PAI

30% CarbonFilledPAI

30% CarbonFilledPAI

UnfilledPBI

CompressionMolded

CompressionMolded


MoldedCompression

MoldedCompression

MoldedCompression



CompressionMolded


MoldedCompression


CompressionMolded


2 Tensile Strength 73°F MPa D638 41 47 40 83 65 72 9 7.5 14 10 75 110 97 76 54 110 110 103 62 90 152 86 110

3 Tensile Modulus of Elasticity 73°F MPa D638 390 500 550 2,760 2,760 3,450 2,550 2,060 2,240 1,720 3,720 4,340 6,9000 5,860 3,650 9,650 9,310 6,200 3,440 3,960 8,270 5,030 5,860


5 Flexural Strength, 73°F MPa D790 21 26 24 110 83 97 17 15 27 14 72 172 160 189 89 158 152 158 82 82 - 124 220

6 Flexural Modulus of Elasticity 73°F MPa D790 531 552 600 3,450 2,760 2,480 2,060 3,450 3,340 2.410 3,680 4,130 6,900 7,580 4,820 6,890 7,930 5,510 3,790 3,790 - 6,890 6,550

7 Shear Strength 73°F MPa D732 33 33 33 76 55 59 17 14 17 12 - 90 100 68 - 76 - 113 - - - - -

8 Compressive Strength, 10% Deformation 73°F MPa D695 21 21 20 103 93 105 48 27 23 26 106 138 150 138 138 193 200 151 138 138 255 296 344

9 Compressive Modulus of Elasticity 73°F MPa D695 524 552 550 2,760 1,793 2,760 1,380 1,720 1,720 1,550 2,350 3,440 3,790 3,440 2,750 4,000 3,620 6,550 2,585 2,410 6,890 6,690 6,200



12 Izod Impact (notched), 73°F - D256 Type “A” No Break No Break No Break 2.12 5.3 2.12 2.65 4.77 - 5.3 7.42 3.18 4,24 3.71 5.3 7.42 5.3 4.24 2.65 5.83 4.77 3.71 2.65


14 Limiting PV (with 4:1 safety factor applied) MPa. cm/min QTM 55007 1,260 630 630 630 570 1,260 3,000 1,680 950 1,680 1,840 1,780 - 4,200 7,360 3,570 3,150 1,570/ 8,410* 4,730 1,570 2,940 9,040 7,880

15 Wear Factor “k” x 10 -10 min/MPa . hr QTM 55010 241 - 120 1,207 2,415 420 385 7,200 2,415 1026 750 4,500 - 1,207 1,570 1,230 1,025 3,600/120* 1,810 3,800 900 1,350 720

16 Coefficient of Linear Thermal Expansion (-40°C to 149°C) cm./cm./°C E-831 (TMA) 4.4 x 10 -5 19.8 x 10 -5 2.0 x 10 -4 9 x 10 -5 9.7 x 10 -5 8.1 x 10 -5 4.5 x 10-5 4.5 x 10 -5 5.4 x 10 -5 10.26x10-5 5.9 x 10 -5 4.7 x 10 -5 2.16x10-5 3.1 x 10-5 4.9 x 10 -5 4.1 x 10 -5 3.8 x 10 -5 2.5 x 10 -5 3.6 x 10 -5 3.6 x 10 -5 1.6 x 10 -5 1.6 x 10 -5 2.3 x 10 -5

17 Heat Deflection Temperature 1,820 kpa °C D648 47 47 47 93 104 82 104 132 93 100 115 160 232 195 250 232 250 280 280 280 - - 427 (DMA)

18 Tg-Glass transition (amorphous) °C D3418 N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A 275 275 275 275 275 400 (DMA)

19 Melting Point (crystalline) peak °C D3418 135 135 135 215 168 255 327 327 - 327 280 340 340 340 340 340 343 N/A N/A N/A N/A N/A N/A

20 Continuous Service Temperature in Air (Max.) (1) °C - 82 135 82 127 82 99 260 260 315 260 220 250 250 250 250 250 250 260 260 260 260 260 340

21 Thermal Conductivity W/°k . M F433 0.41 0.41 0.41 0.34 0.23 0.27 - 0.76 - 0,44 0.30 0.25 0.43 0.25 - 0.91 0.91 0.53 0.53 0.40 0.50 0.50 0.40

22 Dielectric Strength, Short Term kV/mm D149 - - 45.3 19.7 16.5 21.0 - 10.8 - 7.9 19.7 18.9 19.7 - - - - - - - - - 21.6

23 Surface Resistivity ohm/square EOS/ESD S11.11 >1015 >1015 >1015 >1013 >1013 >1013 >105 >1013 <106 >1013 >1013 >1013 >1013 >1013 <1013 <105 <105 >1013 >1013 >1013 - - >1013


25 Dissipation Factor, 10 6 Hz - D150 - 5 x 10-4 - - 0.005 0.02 - 0.008 - 0.008 - 0.003 - - - - - 0.037 0.042 - - - 0.003

26 Flammability @ 3.1 mm (5) - UL 94 HB HB HB HB HB HB V-0 V-0 V-0 V-0 V-0 V-0 V-0 V-0 - V-0 V-0 V-0 V-0 V-0 V-0 V-0 V-0

27 Water Absorption Immersion, 24 Hours % by wt. D570 (2) <0.01 <0.01 <0.01 0.6 0.2 0.06 0.1 0.1 0.1 0.03 0.01 0.1 0.1 0.05 0.07 0.15 0.15 0.4 0.3 0.3 0.3 0.3 0.4


29 Acids, Weak, acetic, dilute hydrochloric or sulfuric acid @23°C A A A L L A A A A A A A A A A A A A A A A A L

30 Acids, Strong, conc. hydrochloric or sulfuric acid @23°C A A A U U L A A A A L L L L L L L L L L L L U

31 Alkalies, Weak, dilute ammonia or sodium hydroxide @23°C A A A L A A A A A A A A A A A A A L L L L L L

32 Alkalies, Strong, strong ammonia or sodium hydroxide @23°C A A A U U U U U U U A A A A A A A U U U U U U

33 Hydrocarbons–Aromatic, benzene, toluene @23°C L L L A A A A A A A A A A A A A A A A A A A A

34 Hydrocarbons–Aliphatic, gasoline, hexane, grease @23°C A A A A A A A A A A A A A A A A A A A A A A A

35 Ketones, Esters, acetone, methyl ethyl ketone @23°C A A A A A A A A A A A A A A A A A A A A A A A

36 Ethers, diethyl ether, tetrahydrofuran @23°C L L L A A A A A A A A A A A A A A A A A A A A

37 Chlorinated Solvents, methylene chloride, chloroform @23°C L L L L L U A A A A A A A A A A A A A A A A A

38 Alcohols, methanol, ethanol, anti-freeze @23°C A A A L A A A A A A A A A A A A A A A A A A A

39 Continuous Sunlight @23°C L L L L L L A A A A L L L A A A A A A A A A L

40 Relative Cost (4) $ $ $ $$ $$ $$+ $$$ $$$$ $$$$$ $$$$ $$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$

41 Relative Machinability (1-10, 1 = Easier to Machine) 2 2 2- 1 1 2 2 2 5 2 3 5 7 7 5 7 8 5 6 6 8 8 10

NOTE: Property data shown are typical average values. A dash (-) indicates insufficient data available for publishing. The metric data listed here are converted from imperial ASTM test values. In the future they will also be available as ISO data. Please consult us for more details.

MEC

HANI

CAL

THE

RMAL

ELEC

TRIC

ALCH

EMIC

ALOT

HER

A = Acceptable Service

L = Limited Service

U = Unacceptable

QTM = Quadrant Test Method

KEY

34

METRIC DATA

Product Description

Units

Test

Method

ASTM

TIVAR®

HPVUHMW-PE

TIVAR®

H.O.TUHMW-PE

TIVAR®

1000Nylatron®

MC901 PA6Acetron®

GP POM-CErtalyte®


135Fluorosint®


MT-01Fluorosint®

207Techtron®

HPV PPSKetron®

1000 PEEKKetron®

GF30Ketron®

HPV PEEK

Ketron®

CM HPVPEEK

Ketron®

CM CA30PEEK

Ketron®

CM 1030HTPEK

Duratron®

T4301 PAIDuratron®

T4501 PAIDuratron®

T4540 PAIDuratron®

T7130 PAIDuratron®

T7530 PAIDuratron®

CU60 PBI



PA6

PremiumPorosity-

freePOM-C

Premium,Solid

LubricantFilled PET


Mica FilledPTFE

Carbon Fiber &


Mica Filled PTFE

Premium,Solid

LubricantFilled PPS

UnfilledPEEK

30% Glass Fiber

Filled PEEK

Premium,Solid Lub.

Filled PEEK

BearingGradePEEK

30% Carbon

Fiber FilledPEEK

30% CarbonFilled

PEK HT

BearingGrade PAI

BearingGrade PAI

BearingGrade PAI

30% CarbonFilledPAI

30% CarbonFilledPAI

UnfilledPBI

CompressionMolded

CompressionMolded


MoldedCompression

MoldedCompression

MoldedCompression



CompressionMolded


MoldedCompression


CompressionMolded


2 Tensile Strength 73°F MPa D638 41 47 40 83 65 72 9 7.5 14 10 75 110 97 76 54 110 110 103 62 90 152 86 110

3 Tensile Modulus of Elasticity 73°F MPa D638 390 500 550 2,760 2,760 3,450 2,550 2,060 2,240 1,720 3,720 4,340 6,9000 5,860 3,650 9,650 9,310 6,200 3,440 3,960 8,270 5,030 5,860


5 Flexural Strength, 73°F MPa D790 21 26 24 110 83 97 17 15 27 14 72 172 160 189 89 158 152 158 82 82 - 124 220

6 Flexural Modulus of Elasticity 73°F MPa D790 531 552 600 3,450 2,760 2,480 2,060 3,450 3,340 2.410 3,680 4,130 6,900 7,580 4,820 6,890 7,930 5,510 3,790 3,790 - 6,890 6,550

7 Shear Strength 73°F MPa D732 33 33 33 76 55 59 17 14 17 12 - 90 100 68 - 76 - 113 - - - - -

8 Compressive Strength, 10% Deformation 73°F MPa D695 21 21 20 103 93 105 48 27 23 26 106 138 150 138 138 193 200 151 138 138 255 296 344

9 Compressive Modulus of Elasticity 73°F MPa D695 524 552 550 2,760 1,793 2,760 1,380 1,720 1,720 1,550 2,350 3,440 3,790 3,440 2,750 4,000 3,620 6,550 2,585 2,410 6,890 6,690 6,200



12 Izod Impact (notched), 73°F - D256 Type “A” No Break No Break No Break 2.12 5.3 2.12 2.65 4.77 - 5.3 7.42 3.18 4,24 3.71 5.3 7.42 5.3 4.24 2.65 5.83 4.77 3.71 2.65


14 Limiting PV (with 4:1 safety factor applied) MPa. cm/min QTM 55007 1,260 630 630 630 570 1,260 3,000 1,680 950 1,680 1,840 1,780 - 4,200 7,360 3,570 3,150 1,570/ 8,410* 4,730 1,570 2,940 9,040 7,880

15 Wear Factor “k” x 10 -10 min/MPa . hr QTM 55010 241 - 120 1,207 2,415 420 385 7,200 2,415 1026 750 4,500 - 1,207 1,570 1,230 1,025 3,600/120* 1,810 3,800 900 1,350 720

16 Coefficient of Linear Thermal Expansion (-40°C to 149°C) cm./cm./°C E-831 (TMA) 4.4 x 10 -5 19.8 x 10 -5 2.0 x 10 -4 9 x 10 -5 9.7 x 10 -5 8.1 x 10 -5 4.5 x 10-5 4.5 x 10 -5 5.4 x 10 -5 10.26x10-5 5.9 x 10 -5 4.7 x 10 -5 2.16x10-5 3.1 x 10-5 4.9 x 10 -5 4.1 x 10 -5 3.8 x 10 -5 2.5 x 10 -5 3.6 x 10 -5 3.6 x 10 -5 1.6 x 10 -5 1.6 x 10 -5 2.3 x 10 -5

17 Heat Deflection Temperature 1,820 kpa °C D648 47 47 47 93 104 82 104 132 93 100 115 160 232 195 250 232 250 280 280 280 - - 427 (DMA)

18 Tg-Glass transition (amorphous) °C D3418 N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A N/A 275 275 275 275 275 400 (DMA)

19 Melting Point (crystalline) peak °C D3418 135 135 135 215 168 255 327 327 - 327 280 340 340 340 340 340 343 N/A N/A N/A N/A N/A N/A

20 Continuous Service Temperature in Air (Max.) (1) °C - 82 135 82 127 82 99 260 260 315 260 220 250 250 250 250 250 250 260 260 260 260 260 340

21 Thermal Conductivity W/°k . M F433 0.41 0.41 0.41 0.34 0.23 0.27 - 0.76 - 0,44 0.30 0.25 0.43 0.25 - 0.91 0.91 0.53 0.53 0.40 0.50 0.50 0.40

22 Dielectric Strength, Short Term kV/mm D149 - - 45.3 19.7 16.5 21.0 - 10.8 - 7.9 19.7 18.9 19.7 - - - - - - - - - 21.6

23 Surface Resistivity ohm/square EOS/ESD S11.11 >1015 >1015 >1015 >1013 >1013 >1013 >105 >1013 <106 >1013 >1013 >1013 >1013 >1013 <1013 <105 <105 >1013 >1013 >1013 - - >1013


25 Dissipation Factor, 10 6 Hz - D150 - 5 x 10-4 - - 0.005 0.02 - 0.008 - 0.008 - 0.003 - - - - - 0.037 0.042 - - - 0.003

26 Flammability @ 3.1 mm (5) - UL 94 HB HB HB HB HB HB V-0 V-0 V-0 V-0 V-0 V-0 V-0 V-0 - V-0 V-0 V-0 V-0 V-0 V-0 V-0 V-0

27 Water Absorption Immersion, 24 Hours % by wt. D570 (2) <0.01 <0.01 <0.01 0.6 0.2 0.06 0.1 0.1 0.1 0.03 0.01 0.1 0.1 0.05 0.07 0.15 0.15 0.4 0.3 0.3 0.3 0.3 0.4


29 Acids, Weak, acetic, dilute hydrochloric or sulfuric acid @23°C A A A L L A A A A A A A A A A A A A A A A A L

30 Acids, Strong, conc. hydrochloric or sulfuric acid @23°C A A A U U L A A A A L L L L L L L L L L L L U

31 Alkalies, Weak, dilute ammonia or sodium hydroxide @23°C A A A L A A A A A A A A A A A A A L L L L L L

32 Alkalies, Strong, strong ammonia or sodium hydroxide @23°C A A A U U U U U U U A A A A A A A U U U U U U

33 Hydrocarbons–Aromatic, benzene, toluene @23°C L L L A A A A A A A A A A A A A A A A A A A A

34 Hydrocarbons–Aliphatic, gasoline, hexane, grease @23°C A A A A A A A A A A A A A A A A A A A A A A A

35 Ketones, Esters, acetone, methyl ethyl ketone @23°C A A A A A A A A A A A A A A A A A A A A A A A

36 Ethers, diethyl ether, tetrahydrofuran @23°C L L L A A A A A A A A A A A A A A A A A A A A

37 Chlorinated Solvents, methylene chloride, chloroform @23°C L L L L L U A A A A A A A A A A A A A A A A A

38 Alcohols, methanol, ethanol, anti-freeze @23°C A A A L A A A A A A A A A A A A A A A A A A A

39 Continuous Sunlight @23°C L L L L L L A A A A L L L A A A A A A A A A L

40 Relative Cost (4) $ $ $ $$ $$ $$+ $$$ $$$$ $$$$$ $$$$ $$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$ $$$$$

41 Relative Machinability (1-10, 1 = Easier to Machine) 2 2 2- 1 1 2 2 2 5 2 3 5 7 7 5 7 8 5 6 6 8 8 10

* Extruded PAI materials can benefit from a post-machine cure cycle.

(1) Data represent Quadrant’s estimated maximum long-term service temperature based on practical field experience.(2) Specimens 1/8” thick x 2” diameter or square.(3) Chemical resistance data are for little or no applied stress. Increased stress, especially localized, may result in more severe attack. Examples of common chemicals also included.

(4) Relative cost of material profiled in this brochure ($ = Least Expensive and $$$$$$ = Most Expensive)(5) Estimated rating based on available data. The UL 94 Test is a laboratory test and does not relate to actual fire hazard. Contact Quadrant for specific UL “Yellow Card” recognition number.

Lit_

Rota

ting

Equi

pmen

t_04

/18

www.quadrantplastics.comQuadrant Engineering Plastic Products Worldwide

EuropeQuadrant EPP Europe B.V.I.P. Noord - Galgenveldstraat 128700 Tielt, Belgium T +32 [0] 51 42 35 11 F +32 [0] 51 42 33 [email protected]

North AmericaQuadrant EPP USA, Inc. 2120 Fairmont AvenuePO Box 14235 - Reading, PA 19612-4235T 800 366 0300 | +1 610 320 6600F 800 366 0301 | +1 610 320 [email protected]

Asia-PacificQuadrant EPP Asia Pacific Ltd60 Ha Mei San Tsuen, Ping ShanYuen Long - NT Hong KongT +852 24702683F +852 [email protected]

You inspire … we materialize®

This brochure and any data and specifications presented here or on our website shall provide promotional and general information about the Engineering Plastic Products (the „Products“) manufactured and offered by Quadrant Engineering Plastic Products („Quadrant“) and shall serve as a preliminary guide. All data and descriptions relating to the Products are of a general informational nature only. Neither this brochure nor any data and specifications presented on our website shall create or be implied to create any legal or contractual obligation. This brochure and any data or specifications herein do not create expressly or by implication any legal, contractual or warranty obligation whatsoever. No warranty of any kind, either express or implied, is made as to the information contained in these pages, including, but not limited to, all warranties provided for by Louisiana law, any implied warranty of merchantability, of fitness for a particular purpose, and any warranty against hidden defects or redhibitory defects or vices. No information in this brochure creates any express or implied warranty that the goods described here in shall conform to any description herein. Quadrant sells the products described herein solely to sophisticated users and not to consumers, and Quadrant assumes no responsibility that any goods described herein will be fit for any particular purpose for which a Quadrant customer may determine to purchase such goods, except and to the sole extent otherwise provided in a separate written contract.

Any illustration of the possible fields of application of the Products shall merely demonstrate the potential of these Products, but any such description does not constitute any kind of covenant or warranty whatsoever. Irrespective of any tests that Quadrant may have carried out with respect to any Product, Quadrant does not possess expertise in evaluating the suitability of its materials or Products for use in specific applications or products manufactured or offered by the customer respectively. It thus remains the customer‘s sole responsibility to test and assess the suitability and compatibility of Quadrant‘s Products for its intended applications, processes and uses, and to choose those Products that according to its assessment meet the requirements applicable to the specific use of the finished product. The customer undertakes all liability in respect of the application, processing or use of the aforementioned information or product, or any consequence thereof, and shall verify its quality and other properties.

Acetron®, Duratron®, Ertalyte®, Fluorosint®, Ketron®, Nylatron®, Proteus®, Sanalite®, Semitron®, Techtron®, TIVAR® are registered trademarks of the Quadrant group of companies.

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