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Definition
Relevance to
package performance
What
affects the OTR of films
Test
principles
Related
Terminology
Definition
OTR (oxygen
transmission rate) is the steady state rate at
which oxygen gas permeates through a film at
specified conditions of temperature and
relative humidity. Value are expressed in
cc/100 in2/24 hr in US standard
units and cc/m2/24 hr in metric (or
SI) units. Standard test conditions are 73°F
(23°C) and 0% RH.
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Relevance to
package performance
The air we breathe is
about 21% oxygen and 79% nitrogen, with very
small concentrations of other gases like
carbon dioxide and argon. Essential to human
and animal life, oxygen gas is also a reactive
compound that is a key player in food
spoilage. Most of the chemical and biological
reactions that create rancid oils, molds, and
flavor changes require oxygen in order to
occur. So, it is not surprising that food
packaging (and some non-food packaging for
products where atmospheric oxygen causes harm)
has progressed and found ways to reduce oxygen
exposure and extend the shelf life of
oxygen-sensitive products.
There are two methods
for reducing product exposure to oxygen via
flexible packaging.
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MAP
(modified atmosphere packaging) is
a process for replacing the air in the
headspace of a package with another gas
before the final seal is made. This is
also called gas flushing. The most common
replacement gases are nitrogen or
nitrogen/carbon dioxide mixtures. The
shelf lives of potato chips, dried fruits,
nuts, and shredded cheese are commonly
extended by this packaging method.
-
Vacuum
packaging is where the atmosphere
is drawn out and eliminated, rather than
being replaced by another gas. This vacuum
forces the flexible material to conform to
the product shape. Meats (fresh and
processed) and cheeses are commonly
packaged this way.
Once air has been
replaced or eliminated from the package, there
must be an adequate oxygen barrier and seal
integrity to keep a low oxygen concentration
inside the pack. Otherwise, the driving force
created by the oxygen partial pressure
differences (21% outside the bag and 0-2%
inside the bag) will cause an ingress of
oxygen and destroy the benefit of removing it
in the first place. OTR values are used to
compare the relative oxygen barrier
capabilities of packaging films. An industry
rule-of-thumb is that a material is considered
a "high oxygen barrier" if its OTR
is less than 1 cc/100 in2/24 hr
(15.5 cc/m2/24 hr).
Table 10 shows OTR
values for common polymer packaging films.
Note that the table is divided into two
sections. The first contains normalized (1
mil) values for common materials. The second
section displays the OTRs for coated or
metallized films where the total film
thickness is unimportant, because the barrier
is primarily coming from the additional layer.
| Film
Type |
OTR
@ 73°F (23°C), 0% RH |
| (cc/100
in2/24 hr) |
(cc/m2/24
hr) |
| The
following OTRs are bulk material
properties displayed at 1 mil.
You may divide by the gauge (in mil)
in order to approximate OTR at a
different thickness. |
| EVOH*
(ethylene vinyl alcohol) |
.005
- .12 |
.08
- 1.9 |
| Biax
Nylon-6 |
1.2
- 2.5 |
18.6
- 39 |
| OPET
(oriented polyester) |
2
- 6 |
31
- 93 |
| OPP |
100
- 160 |
1550
- 2500 |
| Cast
PP |
150
- 200 |
2300
- 3100 |
| HDPE
(high density polyethylene) |
150
- 200 |
2300
- 3100 |
| OPS
(oriented polystyrene) |
280
- 400 |
4350
- 6200 |
| LDPE
(low density polyethylene) |
450
- 500 |
7000
- 8500 |
| The
following OTRs are enhanced by coating
or metallizing. Therefore, these
are not bulk film properties, and
total film thickness has little impact
on the OTR value. |
| Metallized
OPET |
.01
- .11 |
.16
- 1.7 |
| PVOH-coated
OPP (AOH) |
.02 |
.31 |
| Metallized
biax Nylon-6 |
.05 |
.78 |
| PVdC-coated
OPET |
.30
- .50 |
4.7
- 7.8 |
| High
Barrier PVdC-coated OPP |
.30
- .60 |
4.7
- 9.3 |
| PVdC-coated
biax Nylon-6 |
.35
- .50 |
4.7
- 7.8 |
| Metallized
OPP |
1.2
- 10 |
19
- 160 |
| Sealable
PVdC-coated OPP |
1.5
- 3.5 |
23
- 54 |
Table
10: OTR values for common films
*The
range of possible values is especially wide
for EVOH because the value is dependent on the
ethylene content of the particular grade. EVOH
is typically a buried layer, either via
coextrusion or lamination.
|
CAUTION: |
In
order for film oxygen barrier to
contribute its full product protection
value, package seal integrity must be
satisfactory. Poor quality seals can
negate a film's good barrier by
allowing oxygen transmission through
channel leakers and imperfections.
|
Related
information: Many customers ask about
the carbon dioxide (CO2)
and nitrogen (N2)
transmission rates through film.
ExxonMobil does not perform
transmission testing with these gases,
but a value range can be estimated
from OTR values by using the following
relationships. CO2
TR will be 3 to 5 times the OTR value
at 73ºF (23ºC), 0% RH N2
TR will be .2 to .4 times the OTR
value at 73ºF (23ºC), 0% RH For
example, the OTR of 110 AXT is .40
cc/100 in2/24 hr @ 73ºF
(23ºC), 0% RH. Therefore, at the same
conditions, the CO2 TR is
approximately 1.2 - 2.0 cc/100 in2/24
hr and the N2 TR is
approximately .08 to .16 cc/100 in2/24
hr. |
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What affects
the OTR of films
Good oxygen barrier
is achieved by combining functional layers to
create a film with the required barrier, as
well as those other properties necessary to
produce a serviceable package. For example,
EVOH has exceptional OTR properties, but needs
moisture barrier and mechanical properties
provided by layers that are coextruded or
laminated around it.
OTR is most affected
by the following factors.
-
Thickness
of barrier layer: Generally, the
thicker the oxygen barrier-providing
layer, the better the barrier. But there
are process and cost limitations that
restrict the thicknesses that can be
realistically produced or successfully
utilized.
-
Copolymer
ratio, plasticizer content, and
polymerization process: All PVdCs
(or EVOHs or PVOHs) are not created equal.
Properties are compromised during polymer
and product development, so that total
performance in target applications is
optimized. There can be substantial
differences in OTR values depending on the
selections made. For example, both ASB-X
and AXT are PVdC-coated and sealable, but
their OTRs are 4.5 cc/100 in2/24
hr and .40 cc/1 00 in2/24 hr,
respectively. ASB-X has the poorer OTR,
but a broader seal range than AXT.
-
Base film
surface compatibility: The
physical and chemical characteristics of
the base film surface have a major effect
on the OTR after metallization, and to a
lesser degree, after coating. This is
evidenced by Met PET's exceptional
barrier, as well as the difference in OTRs
between various metallized OPP products
(refer to Table 10).
ExxonMobil only
measures and controls OTR for those films that
are modified through coating, coextrusion, or
metallization, and guarantee a maximum OTR
value in the product specification. This
includes AXT, HBS-2, AOH, MET-HB, and MU842.
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Test principles
ExxonMobil
uses MOCON OX-TRAN@ instruments for measuring
OTR. The instrument design and the way we
operate the instrument are consistent with the
ASTM D 3985 standard. ExxonMobil standardizes
its reporting to test conditions of 73°F
(23°C) and 0% RH.
Conceptually,
a test cell looks like Figure 4. Dry nitrogen
gas is swept through a chamber, where the test
film acts as the membrane separating this
stream from an oxygen stream on the other
side. The partial pressure difference creates
a driving force for oxygen molecules to
diffuse through the film to the low pressure
side. The film barrier determines the rate of
oxygen permeation, and this is continuously
measured by a MOCON® patented
coulometric sensor in the outgoing ,stream of
the nitrogen side.
Figure
4: Cross-section of an OTR test cell
The test is complete when equilibrium, or
steady state, is achieved; that is, it is
complete when the sensor detects a constant
amount of oxygen in the nitrogen carrier
stream. The rate of oxygen permeating through
the sample is not changing. This rate is the
sample OTR and is recorded in units of cc/100
in2/24 hr or cc/m2/24 hr
at 73°F (23°C), 0% RH.
This discussion is an overview of how
ExxonMobil measures OTR and was based on
articles and product literature provided by
MOCON®.
There is much more substance to the science
and measurement of mass transfer. For more
information, contact MOCON®
in Minneapolis, MN at (612) 493-6370,
or visit www.mocon.com.
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NOTE: |
It
is important to discuss the effects of
relative humidity on OTR, even though
the ASTM standard procedure is at dry
conditions. Relative humidity has a
dramatic and negative effect on the
OTRs of some materials, most notably
nylon, EVOH and PVOH. The effect is
especially pronounced at RHs over
about 70%. AOH, with its PVOH coating,
is the only ExxonMobil oxygen-barrier
film affected this way. AOH should
only be used as an oxygen barrier in
dry applications. Consult your
ExxonMobil representative.
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Related terminology
PVdC |
PVdC stands for
polyvinylidene chloride, but The Dow
Chemical Company points out in the 2nd
edition of The Wiley Encyclopedia of
Packaging Technology that the use of
this term is not precisely correct. PVdC
suggests a homopolymer resin; when in
fact, all commercial resins are VdC
copolymers and should be referred to as
such. Nevertheless, it is not likely
that our industry will change its ways,
where "PVdC" has become a
generally accepted representation for
the family of VdC copolymers. |
Saran® |
Saran® is a
trademark of The Dow Chemical Company
for its family of PVdC and VdC copolymer
products. |
Oxygen
scavengers |
Oxygen scavengers are
materials that chemically react with
oxygen in a package headspace. They can
be used with MAP in order to attain very
low oxygen concentrations (ppm levels)
that are not achievable with MAP alone.
Most oxygen scavengers used commercially
are packets containing iron powders that
are placed inside a package and consume
headspace oxygen through oxidation
reactions. |
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