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HoneywellHoneywell

High Temperature Membrane for OBIGGS Application

Lisbon11/15/2004

Jim Zhou

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OutlineOutline

• Objectives• Why high temperature membrane?• Fiber spinning conditions• Test results• Conclusions

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ObjectivesObjectives

• Objectives

To develop a high temperature gas separation hollow fiber membrane suitable for the OBIGGS application

• Why high temperature membrane?

Reduce the size and volume of the OBIGG system by taking advantage of higher gas permeability at higher temperatures and reduced cooling requirements at higher OBIGGS operating temperature

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Membrane Material SelectionMembrane Material Selection

Honeywell’s Innovative High Temperature Membrane

• High O2, N2 permeability

• High O2/N2 Selectivity

• Wet spun with very thin selective layer to increase flux

• Less susceptible to contaminants

• Large operating temperature and pressure range

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Membranes and Membrane ModulesMembranes and Membrane Modules

This illustration shows how fast gases like oxygen and moisture permeate the surface of the individual membrane fibers while nitrogen molecules remain

inside and are delivered as the product gas.

Feed Air

Nitrogen

Oxygen

Water Vapor

Nitrogen

Oxygen and water vapor are “fast” gases which quickly permeate the membrane, allowing nitrogen to flow through the fiber bores as the product stream.

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Membranes and Membrane ModulesMembranes and Membrane Modules

Thousands of individual fibers wrapped around a core make up the nitrogen generating hollow fiber membrane module. The engineering of the module is important to maximizing the performance of the whole system.

End Plate

Epoxy Tube Sheet

Support Core

Feed Air O-Rings

Hollow Fibers

Oxygen-Enriched Air

Epoxy TubeSheet

EnrichedNitrogenProduct

Gas

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Fiber Spinning ConditionsFiber Spinning Conditions

Phase inversion/Wet spinning process

PolymerSolvent

Non-SolventOther Additives

Core Fluid

Water Bath

Leaching

Dry Air

• Pros Can produce membrane

with extremely thin selective layer (Asymmetrical membrane structure)

•ConsPorous support layer may not be stable at high

temperaturesComplex spinning and solvent leaching processMembrane selectivity changes with the amount of

solvent left behind

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Typical Fiber Spinning ConditionsTypical Fiber Spinning Conditions

• Fiber spinning condition ranges

Polymer dope rate: 1.2 to 2.5 g/min/per strandSpeed: 75 to 250 ft/min(23 to 76 m/min)Center solvent rate: 0.5 to 2.0 ml/minTemperature: Room to 100oCFiber ID: 100 to 160 micronFiber OD: 150 to 300 micron

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Membrane StructureMembrane Structure

• Thin skin layer with porous support

• High gas flux

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Test ResultsTest ResultsO2/N2 Selectivity vs. O2 Flux

0

2

4

6

8

10

12

0 2 4 6 8 10 12

O2 Flux

O2/

N2

Sel

ecti

vity

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Test ResultsTest Results

Flux Rates Vs. Time at 160C

0

5

10

15

20

25

30

35

40

45

1/15 1/20 1/25 1/30 2/4 2/9 2/14 2/19 2/24

Date

Flu

x

F_inlet

F_prod

F_perm

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Test ResultsTest Results

Oxygen Concentration Vs. Time at 160C

0

5

10

15

20

25

30

35

1/15 1/20 1/25 1/30 2/4 2/9 2/14 2/19 2/24

Date

Oxy

gen

vo

lum

e %

O2_inlet

O2_prod

O2_perm

Start of 160C Test

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Air Separation ModulesAir Separation Modules

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ConclusionsConclusions

• Membrane is stable at operating temperatures up to 160C• Membrane flux increase with increase temperature• Membrane performance influenced by spinning conditions• High temperature membrane offers advantages over

conventional membranes

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The Fourth Triennial The Fourth Triennial International Aircraft Fire and Cabin Safety International Aircraft Fire and Cabin Safety Research ConferenceResearch Conference

The Fourth Triennial The Fourth Triennial International Aircraft Fire and Cabin Safety International Aircraft Fire and Cabin Safety Research ConferenceResearch Conference