Experiments for Characterizing the Fatigue Behavior

Transcription

Elastomer Fatigue Property Mapping – Characterization Service
Fatigue of elastomers is governed by many factors. Through testing and analysis, the important factors can
be systematically quantified to produce a map showing how fatigue performance depends on the conditions
that will be encountered by a part in service.
Testing isn’t a matter of cycling tensile specimens under all conditions. Generating elastomeric strain-life
(s-n) fatigue data sets is extremely time consuming. The use of shorter duration crack growth experiments
and advanced fatigue analysis software from Endurica provides a faster and more versatile method to get
important fatigue data.
Many designers of metal structures make use of strain-life (s-n) data sets. These data sets are generated
by cyclically loading test specimens until failure at each of several strain levels or stress levels occurs. For
elastomeric materials, the creation of s-n data sets can be problematic. Elastomers generally have very low
thermal conductivity, high hysteretic energy and are used in high strain applications.
Reasons why Fatigue and Crack Growth (FCG) testing is more efficient than S-N tests:
S-N tests produce only one point per specimen. One FCG test can easily produce many points that
span a wide range of conditions.
FCG tests can be reliably and inexpensively scheduled and controlled to cover targeted crack growth
rates. S-N tests are more difficult to plan, and require trial and error selection of test conditions.
Because of sensitivity to flaw size, S-N tests inherently exhibit higher scatter than FCG tests. More
replication is required for S-N testing.
Self-heating in S-N specimens can be unrealistically high.
Some elastomers are also very minimum-strain sensitive. This means elastomers that are cycled between
a given maximum strain and zero strain may have a much shorter fatigue life than the same elastomer
cycled between the same maximum strain and a small positive minimum strain. As such, the effects of the
ratio of minimum strain to maximum strain may be significant and additional tests are required.
The general mechanism of fatigue in elastomeric materials is dominated by the initiation and growth of
small cracks. During the last 25 years, there have been significant advances in the use of fatigue crack
growth theory to predict the fatigue life of elastomeric structures. Endurica LLC produces a commercial
software product that uses fatigue crack growth data, along with analysis codes, to estimate the fatigue life
of elastomeric parts. This same analytical software can also be employed to efficiently generate strain-life
data sets for elastomeric materials.
This allows strain-life data sets to be generated more quickly while also enabling generation of strain-life
data sets at various temperatures and at various strain minimum to strain maximum levels, without the
requirement of running multiple cyclic tests for many months under varied conditions.
In addition to the experimental measurements that are collected and delivered, appropriate theories are fit
to the results from each experiment. The result is a complete mathematical description of the material’s
stress-strain and fatigue behavior that is ready for use in comparing different materials under various
operating scenarios, for use in hand-calculations, or for use in analysis software packages such as fesafe/Rubber or the Endurica CL command line fatigue solver.
Endurica LLC  www.endurica.com
1219 West Main Cross, Suite 201  Findlay  Ohio  45840  USA
P: (+1) 419-957-0543  E: [email protected]
Page 1 of 13
Fatigue Property Map Prices
Item
FPM-C
October 2014. Pricing subject to change.
Description
Price
Elastomer Fatigue Property Map – Core Module



$7,750
Required for all fatigue analyses
one temperature between -40°C and 150°C
fully relaxing (R = 0) conditions
Deliverables
Experiments




Analysis and Reporting
static tearing raw data
fatigue crack growth raw data (20
hour procedure)
monotonic tensile to failure raw
data
cycles to failure tensile raw data,
2 strain levels





FPM-IS
critical tearing energy Tc
tensile strain, stress, energy at
break
fatigue crack growth rate curve
and its parameters (rc, and F)
crack precursor size c0
calculation and sensitivity
analysis
strain-life, stress-life, and energylife fatigue curves
Elastomer Fatigue Property Map – Intrinsic Strength Module
 Recommended for cases with fatigue life longer than 106 cycles
$2,445
Deliverables
Experiments

FPM-EL
cutting force raw data, 3 strain
levels



cutting vs. tearing curve
intrinsic strength T0
fatigue threshold strain, stress,
energy (if ordered with FPM-C)
Elastomer Fatigue Property Map – Extended Life Module


Recommended for cases with fatigue life longer than 106 cycles, and when
ageing must be taken into account.
Note: It is required to run FPM-IS in order to run this Module.
Deliverables
Experiments



ageing in oven at 3 temperatures
for 3 time periods: 3 days, 10
days, 30 days
static tearing raw data, 3 ageing
periods x 3 ageing temperatures
cutting force raw data, 3 strain
levels x 3 ageing periods x 3
ageing temperatures






cutting vs. tearing curve at each
aged condition
intrinsic strength T0 vs. ageing
curve
tearing energy Tc vs. ageing
curve
fatigue threshold strain, stress,
energy vs. ageing curves (when
ordered with FPM-C)
parameters specifying ageing
time and temperature
dependence of T0 and Tc
extrapolation of ageing effects to
longer timescales for an
application-specific temperature
Page 2 of 13
$22,495
FPM-NR
Elastomer Fatigue Property Map – Non-relaxing Module




$3,000
Recommended for cases where fatigue loading is never fully relieved to zero
test is run under a range of nonrelaxing (R > 0) conditions
Note: It is required to run FPM-C in order to run this Module.
Deliverables
Experiments

FPM-TH

raw data from fatigue crack
growth arrest procedure with
minimum strain sweep

strain crystallization functions
F(R) and x(R)
Haigh diagram showing
sensitivity to minimum strain of
crack nucleation life
Elastomer Fatigue Property Map –Thermal Extension Module



$12,000
Recommended for cases involving significant self-heating or thermal gradients
three additional (to FPM-C) temperatures between -40°C & 150°C
Note: It is required to run FPM-C in order to run this Module.
Deliverables
Experiments



FPM-H23
static tearing raw data at 3
temperatures
cyclic stress strain raw data at
room temperature + 3 other
temperatures
thermal conductivity, specific heat
& density measurements



heat generation law parameters
describing dependence of
hysteresis on strain and
temperature
tear strength vs. temperature
fatigue crack growth rate law
temperature sensitivity coefficient
Elastomer Fatigue Property Map –Hyperelastic Module (23°C)

$1,905
Required as a prerequisite to Finite Element Analysis, lab ambient temperature
Deliverables
Experiments



FPM-HX
simple tension, slow cyclic
loading, raw data
planar tension, slow cyclic
loading, raw data
biaxial tension, slow cyclic
loading, raw data


Identification of a suitable
hyperelastic function and
parameters for FEA
Identification of parameters for
specifying Mullins effect in
ABAQUS or ANSYS
Elastomer Fatigue Property Map –Hyperelastic Module (-40°C<T<150°C)


Required as a prerequisite to Finite Element Analysis
Deliverables
Experiments



simple tension, slow cyclic
loading, raw data
planar tension, slow cyclic
loading, raw data
biaxial tension, slow cyclic
loading, raw data


Identification of a suitable
hyperelastic function and
parameters for FEA
Identification of parameters for
specifying Mullins effect in
ABAQUS or ANSYS
Page 3 of 13
$2,585
Ordering Instructions:
1) Send Purchase Order specifying number of materials and tests to be run, and the email
address to which results should be delivered, to:
Endurica LLC
[email protected]
1219 West Main Cross, Suite 201
Findlay, OH 45840
USA
Phone: +1-419-957-0543
2) Test specimens are die-cut from customer-provided sheets of approximate dimensions
150 mm x 150 mm x 1-2 mm. Please see the Fatigue Property Map Material Shipment
Form on the following page for the number of material slabs to send to Axel Products, Inc.
a. Label each slab with the material identifier you want us to use in reporting.
b. Complete the Fatigue Property Map Material Shipment Form for each material
and include it with your material samples.
3) Test execution times may vary, depending on lab backlog and Modules requested. Once
testing, analysis and reporting are complete, you will receive an email from Endurica
containing the analysis and summary report, and all raw data files.
Notes:
All results delivered via email. The raw data is delivered in an ASCII format. The analysis and summary report is
delivered in PDF format.
Customer data and materials will be retained for 1 year after initial data delivery.
Purchase Order, VISA, MasterCard, AMEX, and Discover Card are accepted methods of payment.
Terms: NET 30 Days after Delivery of Final Report and Data.
Page 4 of 13
Fatigue Property Map Material Shipment Form
***Include one form for each material in your shipment***
1) Check the items being requested, and complete the customer specs:
 Item
Module
Customer Specifications
Test Temp:
Test Freq:
Slabs*
FPM-C
Core Fatigue Testing
5
FPM-IS
Intrinsic Strength
FPM-EL
Extended Life
FPM-NR
Nonrelaxing
FPM-TH
Thermal Extension
Test Temps (3):
6
FPM-H23
Hyperelastic (23 °C )
Peak strain levels:
4
FPM-HX
Hyperelastic (other
temperatures)
Peak strain levels:
Test Temp:
4
3
Ageing Oven Temps (3):
30
1
Total Slabs Sent
Customer Notes:
* Nominal slab dimensions are 150 mm x 150 mm x 1-2 mm.
2) Attach a business card or write the contact information of the person responsible for
specifying this testing.
3) Ship samples to:
Axel Products, Inc.
2255 S. Industrial Hwy.
Ann Arbor MI 48104
USA
Phone: +1-734-994-8308
Fax: +1-734-994-8309
Page 5 of 13
Analysis and Summary Report Examples
Figure 1. Example Table of Contents page for summary report.
Page 6 of 13
Fatigue Property Mapping – Core Module Example Results (FPM-C)
Figure 2. Typical crack tip images collected during fatigue testing. Each contour represents the crack tip
shape at a given number of cycles. Colors indicate time, with blue at the beginning of the test, and deep
red at the end.
rc
T 
dc
 rc  
dN
 Tc 
F
Tc
F
Figure 3. Fatigue crack growth rate observations and model fit parameters.
Page 7 of 13
cf
Nf 
1
 r(T (
c0
max
, c ))
dc
Figure 4. Crack nucleation experiments overlaid with computed strain-life curve corresponding to crack
precursor size c0. Dotted lines show the effect of crack precursor size variation on the strain-life curve.
Fatigue Property Mapping – Intrinsic Strength Module Example Results (FPM-IS)
dc
dN
 mm 


 cyc 
Crack growth rate
Endurance Limit
108
Ultimate Strength
mm
cyc

Tc T 
J 
2 
m 
T0
Energy Release Rate
Figure 5. The fatigue endurance limit T0 is the highest energy release rate that can be carried without
incurring fatigue crack growth. Its value reflects the intrinsic strength of the polymer chains that must be
broken in order to propagate a crack. It is measured via cutting experiments with a highly sharpened,
instrumented microtome blade.
Page 8 of 13
Intrinsic Strength T0, J/m2
Fatigue Property Mapping – Extended Life Module Example Results (FPM-EL)
120
23 degC
100
50 degC
80
75 degC
60
100 degC
40
20
0
1
10
100
Oven Ageing time, days
Figure 6. Evolution of the Intrinsic Strength T0 with Oven Ageing time and temperature.
Tear Strength Tc, J/m2
30000
23 degC
25000
50 degC
20000
75 degC
15000
100 degC
10000
5000
0
1
10
100
Oven Ageing time, days
T0 Ageing Rate, times slower than
100C
Figure 7. Evolution of the Tear Strength Tc with Oven Ageing time and temperature.
10
3 days
1
k ref
k
0.1
0.0025
0.0027
e
Ea ,T0  1 1
 
R  T Tref
10 days




0.0029
30 days
0.0031
0.0033
0.0035
1/T
Figure 8. Determination of ageing rate dependence on time and temperature for Intrinsic Strength T0.
Page 9 of 13
Tc Ageing Rate, times slower than
100C
10
1
3 days
k ref
0.1
0.0025
k
e
Ea ,Tc  1 1
 
R  T Tref
0.0027
10 days




30 days
0.0029
0.0031
0.0033
0.0035
1/T
Figure 9. Determination of ageing rate dependence on time and temperature for Tear Strength Tc.
Fatigue Property Mapping – Nonrelaxing Module Example Results (FPM-NR)
Figure 10. Crack tip images obtained during crack arrest experiments. Red images show the crack tip
while growing under fully relaxing conditions. Blue images show the crack tip while growing under
nonrelaxing conditions.
x(R)
Figure 11. Typical strain-crystallization function x(R), showing dependence on the degree of nonrelaxation
ratio R = Tmin / Tmax (where Tmin and Tmax are the energy release rate cycle extremes).
Page 10 of 13
Figure 12. Typical Haigh diagram for simple tension/compression loading, computed based on crack
growth measurements and crack precursor size inferred from nucleation experiments. Contours are
colored and labeled according the the base 10 logarithm of the fatigue crack nucleation life.
Fatigue Property Mapping – Thermal Module Example Results (FPM-TH)
Figure 13. Dependence of tearing energy Tc on specimen temperature.
Fatigue Property Mapping – Hyperelastic Module Example Results (FPM-H23)
Page 11 of 13
N
W 
i 1
2 i

2
i

i
1

 2 i  3 i  3
1
r
 Wmax  W 

 m   Wmax 
  1  erf 
Figure 14. The lefthand plot shows typical hyperelastic law fit to stress-strain curves measured in simple
(blue), planar (green) and equibiaxial (red) tension. Observations are shown with symbols, best fit with
solid lines. The righthand plot shows typical Mullins law fit to cyclic stabilized stress-strain curves.
Page 12 of 13
About This Service
The service enables engineers to obtain, from a commercial source, highly reliable, affordable
measurements suitable for use in fatigue analysis.
Training on the experimental procedures and analysis for fatigue life prediction is available, see
the website below for more information and schedule.
About Endurica LLC
Endurica LLC develops the world’s most versatile and best-validated fatigue life simulation
system for elastomers. Through its technology and services, Endurica empowers its customers to
analyze real-world fatigue performance of elastomers at the design stage, when the greatest
opportunity exists to influence performance, and before investment in costly fatigue testing of
prototypes. The company was founded in 2008.
www.endurica.com
About Axel Products
Axel Products provides testing services for engineers and analysts. The focus is on the
characterization of nonlinear materials such as elastomers and plastics. Data from the Axel
laboratory is often used to develop material models in finite element analysis codes such as
ABAQUS, fe-safe/Rubber, MSC.Marc, ANSYS and LS-Dyna. Testing services are also provided
to examine sealing and fatigue problems, long term thermal mechanical testing and high strain rate
testing. The company was founded in 1994.
www.axelproducts.com
Page 13 of 13

Experiments for Characterizing the Fatigue Behavior

Transcription

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