Designation: D 1646 – 04
Standard Test Methods for
Rubber—Viscosity, Stress Relaxation, and Pre-Vulcanization
Characteristics (Mooney Viscometer)1
This standard is issued under the fixed designation D 1646; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (e) indicates an editorial change since the last revision or reapproval.
This standard has been approved for use by agencies of the Department of Defense.
1. Scope
1.1 These test methods describe procedures for measuring a
property called Mooney viscosity. Mooney viscosity is defined
as the shearing torque resisting rotation of a cylindrical metal
disk (or rotor) embedded in rubber within a cylindrical cavity.
The dimensions of the shearing disk viscometer, test tempera-
tures, and procedures for determining Mooney viscosity are
defined in these test methods.
1.2 When disk rotation is abruptly stopped, the torque or
stress on the rotor decreases at some rate depending on the
rubber being tested and the temperature of the test. This is
called ’stress relaxation’ and these test methods describe a test
method for measuring this relaxation.
NOTE 1—Viscosity as used in these test methods is not a true viscosity
and should be interpreted to mean Mooney viscosity, a measure of
shearing torque averaged over a range of shearing rates. Stress relaxation
is also a function of the test configuration and for these test methods the
results are unique to the Mooney viscometer.
1.3 When compounded rubber is placed in the Mooney
viscometer at a temperature at which vulcanization may occur,
the vulcanization reaction produces an increase in torque.
These test methods include procedures for measuring the initial
rate of rubber vulcanization.
1.4 The values stated in SI units are to be regarded as the
standard. The values given in parentheses are for information
only.
1.5 ISO Standard 289 Parts 1 and 2 also describes the
determination of Mooney viscosity and pre-vulcanization char-
acteristics. In addition to a few insignificant differences there
are major technical differences between ISO 289 and this test
method in that ISO 289 does not provide for sample prepara-
tion on a mill, while this test method allows milling sample
preparation in some cases prior to running a Mooney viscosity
test. This can result in different viscosity values for some
rubbers.
1.6 This standard does not purport to address all of the
safety concerns, if any, associated with its use. It is the
responsibility of the user of this standard to establish appro-
priate safety and health practices and determine the applica-
bility of regulatory limitations prior to use.
2. Referenced Documents
2.1 ASTM Standards: 2
D 1349 Practice for Rubber—Standard Temperatures for
Testing
D 1418 Practice for Rubber and Rubber Latices— Nomen-
clature
D 1485 Test Methods for Rubber from Natural Sources—
Sampling and Sample Preparation
D 3182 Practice for Rubber—Materials, Equipment, and
Procedures for Mixing Standard Compounds and Prepar-
ing Standard Vulcanized Sheets
D 3185 Test Methods for Rubber—Evaluation of SBR
(Styrene-Butadiene Rubber) Including Mixtures with Oil
D 3186 Test Methods for Rubber—Evaluation of SBR
(Styrene-Butadiene Rubber) Mixed with Carbon Black or
Carbon Black and Oil
D 3896 Practice for Rubber from Synthetic Sources—
Sampling
D 4483 Practice for Determining Precision for Test Method
Standards in the Rubber and Carbon Black Industries
2.2 ISO Standard:3
ISO 289 Rubber, Unvulcanized—Determinations Using the
Shearing Disk Viscometer,
Part 1 Determination of Mooney Viscosity, and
Part 2 Determination of Prevulcanization Characteristics.
3. Terminology
3.1 Definitions of Terms Specific to This Standard:
3.1.1 Mooney viscosity, n—a measure of the viscosity of a
rubber or rubber compound determined in a Mooney shearing
1 These test methods are under the jurisdiction of ASTM Committee D11 on
Rubber and is the direct responsibility of Subcommittee D11.12 on Processability
Tests.
Current edition approved Jan. 1, 2004. Published February 2004. Originally
approved in 1959. Last previous edition approved in 2003 as D 1646 – 03a.
2 For referenced ASTM standards, visit the ASTM website, www.astm.org, or
contact ASTM Customer Service at service@astm.org. For Annual Book of ASTM
Standards volume information, refer to the standard’s Document Summary page on
the ASTM website.
3 Available from American National Standards Institute (ANSI), 25 W. 43rd St.,
4th Floor, New York, NY 10036.
1
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959, United States.
disk viscometer; viscosity is indicated by the torque required to
rotate a disk embedded in a rubber specimen and enclosed in
the die cavity under specified conditions.
3.1.2 pre-vulcanization characteristics, n— for a vulcaniz-
able compound, a measure of the time to the incipient
vulcanization and the rate of cure during the early stages of
vulcanization.
3.1.3 stress relaxation, n—the response of a raw or com-
pounded rubber to a rapid cessation of flow or a sudden
deformation; specific to the use of the shearing disk viscom-
eter, it takes the form of a decaying level of stress initiated by
suddenly stopping the rotation of the disk.
3.1.4 test temperature, n—the steady-state temperature of
the closed dies with rotor in place and the cavity empty; this
steady-state temperature shall be measured within the dies as
described in 6.1.3.
4. Summary of Test Methods
4.1 These test methods are divided into three parts:
4.1.1 Part A—Viscosity: This test method describes the
measurement of the Mooney viscosity. The Mooney viscosity
is measured by a metal disk embedded in a rubber specimen
contained in a rigid cylindrical cavity maintained at a specified
pressure and temperature. The disk is slowly and continuously
rotated in one direction for a specified time. The resistance to
this rotation offered by the rubber is measured in arbitrary
torque units as the Mooney viscosity of the specimen.
4.1.2 Part B—Stress Relaxation: This test method de-
scribes the procedure to measure stress relaxation. At the end
of a Mooney viscosity test, the rotation of the metal disk is
suddenly stopped and the rate of decrease of torque is
monitored as a function of time.
4.1.3 Part C—Pre-Vulcanization Characteristics: This test
method describes how pre-vulcanization properties may be
measured. The viscosity of vulcanizable rubber compounds is
recorded during heating at a specified temperature. The mini-
mum viscosity and the times for the viscosity to increase by
specified amounts are used as arbitrary measures of the start
and rate of vulcanization.
5. Significance and Use
5.1 Viscosity—Viscosity values determined by this test
method depend on molecular structure, molecular weight, and
non-rubber constituents that may be present. Since rubber
behaves as a non-Newtonian fluid, no simple relationship
exists between the molecular weight and the viscosity. There-
fore, caution must be exercised in interpreting viscosity values
of rubber, particularly in cases where molecular weight is very
high. For example, as the molecular weight increases, the
viscosity values for IIR polymers (butyl rubbers) reach an
upper limit of about 80, at 100°C (212°F) using a large rotor at
a rotation speed of 2 r/min, and may then decrease to
considerably lower values. For these higher molecular weight
rubbers, better correlation between viscosity values and mo-
lecular weight is obtained if the test temperature is increased.
5.2 Stress Relaxation—The stress relaxation behavior of
rubber is a combination of both an elastic and a viscous
response. Viscosity and stress relaxation behavior do not
depend on such factors as molecular weight and non-rubber
constituents in the same way. Thus both of these tests are
important and complement each other. A slow rate of relaxation
indicates a higher elastic component in the overall response,
while a rapid rate of relaxation indicates a higher viscous
component. The rate of stress relaxation has been found to
correlate with rubber structure characteristics such as molecu-
lar weight distribution, chain branching, and gel content.
5.3 Pre-Vulcanization Characteristics—The onset of vulca-
nization can be detected with the Mooney viscometer as
evidenced by an increase in viscosity. Therefore, this test
method can be used to measure incipient cure (scorch) time and
the rate of cure during very early stages of vulcanization. This
test method cannot be used to study complete vulcanization
because the continuous rotation of the disk will result in
slippage when the specimen reaches a stiff consistency.
6. Apparatus
6.1 Mooney Viscometer—An instrument consisting of a
motor-driven rotating disk within a cylindrical die cavity
formed by two dies maintained at specified conditions of
temperature and die closure force. The Mooney viscometer
measures the effect of temperature and time on the viscosity of
rubbers. If the stress relaxation test is to be performed, the
instrument must be capable of quickly stopping the rotation of
the disk and monitoring the relaxation of stress versus time.
The die-rotor relationship of an example design is shown in
Fig. 1. The Mooney viscometer shall incorporate the following
components:
6.1.1 Dies—The dies and die holders forming the die cavity
shall be fabricated from a nondeforming tool steel, shall have
an unplated finish, and shall be hardened to a Rockwell
hardness of 60 HRC minimum. The dimensions of the die
cavity, measured from the highest surfaces, shall be 50.93 6
0.13 mm (2.005 6 0.005 in.) in diameter and 10.59 6 0.03 mm
(0.417 6 0.001 in.) in depth. The surfaces of the die cavity
shall either be serrated or contain V-grooves to minimize
slippage of the specimen.
NOTE 2—The two types of dies may not give the same results.
6.1.1.1 Serrated Dies—When the cavity is formed from
four pieces of steel, serrations on the surfaces of the dies and
die holders are used. These serrations consist of rectangular
grooves 0.8 6 0.02 mm (0.031 6 0.0008 in.) wide with a
uniform depth of not less than 0.25 mm (0.010 in.) nor more
than 0.38 mm (0.015 in.). The grooves shall be vertical and
shall be cut on 1.6 6 0.04 mm (0.063 6 0.002 in.) centers. The
serrations of the dies shall consist of two sets of such grooves
at right angles to each other.
6.1.1.2 Radial Grooved Dies—When the die cavity is
formed from two pieces of steel, radial V-grooves are used only
on the flat surfaces of the die cavity. The grooves shall be
spaced at 20° intervals and shall form a 90° angle in the die
surfaces with the bisector of the angle perpendicular to the
surface. They shall extend from the 7-mm (0.281-in.) circle to
the 47-mm (1.875-in.) circle in the upper die and from the
12-mm (0.472-in.) circle to the 47-mm circle in the lower die.
The grooves shall be 1 6 0.1 mm (0.04 6 0.004 in.) wide at
the surface.
D 1646 – 04
2
6.1.1.3 Mounting of Dies—The dies shall be an integral part
of or mounted on platens equipped with a heating device and
controls capable of maintaining the die cavity at the specified
test temperature with a tolerance of 60.5°C (61°F) at equi-
librium conditions.
6.1.1.4 Die Closure—The viscometer shall have a suitable
device for opening and closing the platens and dies and for
holding them closed during a test. During a test it is extremely
important that the die cavity be held closed with the correct
force. To obtain the correct closing force for the mechanical-
type closures, follow explicitly either the manufacturer’s rec-
ommendation or other procedure of equal reliability.4 Pneu-
matically closed dies shall be held closed during the test with
a force of 11.5 6 0.5 kN (2585 6 115 lbf). A greater force may
be required to close the dies when testing extremely tough
stocks. At least 10 s before the motor is started, the force
should be set to 11.5 6 0.5 kN. The die closure shall be such
that a piece of thin soft tissue (with a thickness not greater than
0.04 mm (0.0015 in.)) placed between the meeting surfaces
will retain a continuous pattern of uniform intensity when the
dies are closed upon it. A nonuniform pattern indicates wear of
the die holder surface, misalignment, or distortion of dies and
die holders. Any of these situations will result in undue leakage
and erroneous results.
NOTE 3—For mechanical-type closure viscometers, the pressure on the
die cavities may change if the viscometer is used at a different temperature
than that at which it is adjusted.
6.1.2 Rotors—Two rotors are specified, differing only in
their diameter. They shall be fabricated from a nondeforming
tool steel, shall have an unplated finish and shall be hardened
to a Rockwell hardness of 60 HRC minimum. The large rotor
shall be 38.10 6 0.03 mm (1.500 6 0.001 in.) in diameter and
5.54 6 0.03 mm (0.218 6 0.001 in.) in thickness as measured
from the highest points. The small rotor shall conform to the
large rotor except the diameter shall be 30.48 6 0.03 mm
(1.200 6 0.001 in.). The serrations on the face of the rotor shall
conform to the requirements for the serrated dies given in
6.1.1.1 and the serrations on the edge of the rotor shall conform
to the requirements specified for the serrated die holders. The
rotor head shall be securely mounted perpendicularly to a
suitable straight cylindrical stem not exceeding 11 mm (0.433
in.) in diameter. The rotor head shall be positioned so that the
top and bottom surfaces are 2.54 6 0.10 mm (0.100 6 0.005
in.) from the surfaces of the top and bottom dies, respectively,
when the dies are closed. The wear tolerance from the center
position should not exceed 60.25 mm (60.010 in.). A suitable
seal shall be provided in the lower die having a minimum
clearance and constant torque when the machine is run empty.
The eccentricity, or runout, shall not exceed 0.1 mm.
6.1.2.1 Rotor wear will affect test results. Any rotor worn to
such an extent that the rotor diameter is less than the minimum
diameter shown in this procedure shall not be used.
4 Decker, G. E., “Note on the Adjustment of the Mooney Viscometer Die
Closure,” ASTM Bulletin, No. 195, January 1954, p. 51.
FIG. 1 Relationship of Platens, Dies, and Rotor in a Typical Shearing Disk Viscometer
D 1646 – 04
3
6.1.2.2 Rotor Drive—The disk shall be rotated relative to
the dies at a rotational rate of 0.21 rad/s (2.0 r/min), unless
otherwise specified. The permissible tolerance shall be 60.002
rad/s (60.02 r/min).
6.1.2.3 Rotor Stop—If the stress relaxation test is to be
performed, the instrument shall be capable of stopping the
rotor within 0.1 s.
6.1.3 Temperature Measuring System—Since the measure-
ment of the temperature of the rubber in the die cavity is
difficult and impractical, the temperature of the closed dies
shall be measured with the rotor in place and the cavity empty.
The temperature measuring system shall consist of platinum
resistance temperature sensors, thermocouples, or thermistors.
Calibrated platinum resistance temperature sensors capable of
indicating the temperature to within 60.25°C (60.5°F) are
preferred. When calibrated thermocouples (copper-constantan,
Type T0.25 mm, or 30 wire gage are suggested) or thermistors
are used, they shall be capable of indicating the temperature to
at least 60.5°C (61°F). A temperature sensor shall be located
in each die for control of the die temperature. The active
element of the sensor shall be 3 to 5 mm (0.12 to 0.20 in.) from
the surface of the die and 15 to 20 mm (0.6 to 0.8 in.) from the
rotor axis.
6.1.4 Torque Measuring System—The torque measuring
system shall be designed to measure zero torque when the rotor
is turning in an empty cavity, and to measure 100 6 0.5
Mooney units when a torque of 8.30 6 0.02 N-m (73.5 6 0.2
lbf-in.) is applied to the rotor shaft. If the stress relaxation test
is to be performed, the torque measuring system must reset to
a zero force for a stationary rotor. The torque measuring system
shall record the torque during the relaxation test at minimum
rates of one reading each second for the first 6 s after the rotor
is stopped, one reading each 3 s for the next 24 s, one reading
each 6 s for the next 30 s, and one reading each 12 s for the
remainder of the relaxation test.
6.2 Mill—A laboratory rubber mill conforming to the re-
quirements in Practice D 3182 and set as described in 7.2 of
this test method shall be used when preparing mill massed
samples.
7. Sample Preparation
7.1 Condition the sample obtained in accordance with Test
Methods D 1485 or Practice D 3896 until it has reached room
temperature (23 6 3°C (73 6 5°F)) throughout.
7.2 The sample may be tested as received, unmassed, or it
may be massed. Better repeatability within labs and reproduc-
ibility between labs is normally obtained on unmassed
samples. However, the sample may be massed to expel air, to
consolidate particles, or to modify it, if necessary. When mill
massing is performed, use the sample preparation steps shown
in 7.2 and as specified in Table 1 for the type of rubber being
tested. When specimens cannot be easily cut from the un-
massed material and mill massing is not appropriate, the
manufacturer of the material should be asked to recommend an
alternate sample preparation procedure. For best reproducibil-
ity of results, minimum work (shear) should be done to the
material during sample preparation.
7.2.1 When NR rubber samples are mill massed, pass 250 6
5 g of the sample between the rolls of the standard laboratory
mill as described in Practice D 3182 having a roll temperature
of 70 6 5°C (158 6 9°F) and having a distance between the
rolls of 2.5 6 0.1 mm (0.1 6 0.005 in.) as determined by a lead
slug. Do not allow the sample to rest between passes or to band
on the mill rolls at any time. Roll the sample and immediately
insert it endwise in the mill for another pass. Repeat this
procedure until a total of ten passes have been completed.
Sheet the sample on the tenth pass.
7.2.2 When rubber samples other than NR, EPDM, or EPM
are mill massed, pass 250 6 5 g of the sample between the rolls
of the standard laboratory mill as described in Practice D 3182
having a roll temperature of 50 6 5°C (122 6 9°F) and having
a distance between the rolls of 1.4 6 0.1 mm (0.055 6 0.005
in.) as determined by a lead slug. Do not allow the sample to
rest between passes or to band on the mill rolls at any time.
Immediately fold the sample in half and insert the folded end
into the mill for a second pass. Repeat this procedure until a
total of nine passes have been completed. Immediately insert
the rubber without folding into the mill for a tenth pass.
TABLE 1 Standard Viscosity Test Conditions
Type RubberA Sample Preparation,See Section Test Temperature, °C
B Running Time, minC
IRM 241 7.1 and 7.3 100 6 0.5 or 1256 0.5 8.0
Unmassed sample 7.1 and 7.3 Use conditions listed below for type rubber being tested.
NR 7.1 and 7.2.1 (if massed) 100 6 0.5 4.0
BR 7.1 and 7.2.2 (if massed) 100 6 0.5 4.0
CR
IR
NBR
SBR
BIIR 7.1 and 7.2.2D (if massed) 100 6 0.5 or 125 6 0.5 8.0
CIIR
IIR
EPDM 7.1 and 7.2.2 (if massed) 125 6 0.5 4.0
EPM
Synthetic rubber black masterbatch 7.1 and 7.2.3 (if massed) 100 6 0.5 4.0
Compounded stock reclaimed material 7.1 and 7.3 100 6 0.5 4.0
Miscellaneous If similar to any group above, test accordingly. If not, establish a procedure.
A See Practice D 1418.
B Test temperatures are 100 6 0.5°C (212 6 1°F) or 1256 0.5°C (257 6 1°F).
C Time after the standard 1.0-min warm-up period at which the viscosity measurement is made.
D If no air bubbles are visible in the sample, 7.2.2 may be omitted.
D 1646 – 04
4
7.2.3 When EPDM or EPM rubber samples are mill massed,
pass 250 6 5 g of the sample between the rolls of the standard
laboratory mill as descri