Work done in the period Jan. - June 1994 is summarized. Two threads of research have been followed. First, the thermodynamics approach was used to model the chemical and mechanical responses of composites exposed to high temperatures. The thermodynamics approach lends itself easily to the usage of variational principles. This thermodynamic-variational approach has been applied to the transpiration cooling problem. The second thread is the development of a better algorithm to solve the governing equations resulting from the modeling. Explicit finite difference method is explored for solving the governing nonlinear, partial differential equations. The method allows detailed material models to be included and solution on massively parallel supercomputers. To demonstrate the feasibility of the explicit scheme in solving nonlinear partial differential equations, a transpiration cooling problem was solved. Some interesting transient behaviors were captured such as stress waves and small spatial oscillations of transient pressure distribution

Mcmanus, Hugh L.

English

NASA Technical Reports Server

NASA-CR-196319
j •
/j • J
"7 J
Modeling of Outgassing and Matrix Decomposition
in Carbon-Phenolic Composites
NASA Marshall Grant NAG8-295
Semi-Annual Report
for the period January 1994--June 1994
Submitted to Dr. Roy Sullivan
ED24
George C. Marshall Space Flight Center
MSFC, AL 35812
July, 1994
by
Hugh L. McManus
Class of 1943 Assistant Professor
Principal Investigator
p,.
'J" I'_
I ,-- _0
@, t- 0
Z _ 0
TECHNOLOGY LABORATORY FOR ADVANCED COMPOSITES
Department of Aeronautics and Astronautics, Room 33-311
Massachusetts Institute of Technology
77 Massachusetts Avenue
Cambridge, Massachusetts 02139
https://ntrs.nasa.gov/search.jsp?R=19940032963 2020-06-16T11:42:36+00:00Z

Introduction
This report summarizes the work done in the period January 1994 through June 1994 on
the "Modeling of Outgassing and Matrix Decomposition in Carbon-Phenolic Composites"
program.
Progress
Two threads of research have been followed. First, the thermodynamics approach was
used to model the chemical and mechanical responses of composites exposed to high temperatures.
This approach was first proposed by Sullivan [1]. The thermodynamics approach lends itself
easily to the usage of variational principles. This thermodynamic-variational approach has been
applied to the transpiration cooling problem. In transpiration cooling, a porous solid is cooled by
gas flowing from the cool end to the hot end. The governing equation for the temperature
distribution was obtained for the steady-state case.
The second thread is the development of a better algorithm to solve the governing equations
resulted from modeling. The resulting nonlinear, partial differential equations are very complex.
The complexities are increased even more when detailed material models are included such as
multi-stage chemical reactions and non-ideal gases. Previously, implicit finite difference method
was used to solve the governing equations. Although the implicit method is relatively stable, it
was found that detailed material models cannot be easily incorporated into the implicit finite
difference method. Explicit finite difference method is explored as an alternate numerical method
to solve the governing equations. In the explicit method, detailed material models can be included
into the algorithm much easier than the implicit method. The explicit method is also highly suitable
for solution on massively parallel supercomputers such as SCOUT, MIT's new ARPA-sponsored
Thinking Machines CM-5.
To demonstrate the feasibility of the explicit scheme in solving nonlinear partial differential
equations, a sample problem was solved using SCOUT. The sample problem was a transpiration
cooling problem, which resembles the composite ablative problem in that the solution requires
solving simultaneously the continuity, energy, and momentum equations. Some interesting
transient behaviors were captured such as stress waves and small spatial oscillations of transient
pressure distribution. The results of this study were presented at NASA-Langley in April 1994. A
set of viewgraphs from this presentation are attached.

Current Status
The thermodynamic-variational approach is currently been pursued. Using the approach,
governing equations for material responses of composites exposed to high temperatures will be
derived. Biot has done some extensive work in developing the thermodynamic-variational
approach in references [2,3]. Our work will follow Biot's development closely.
The ablative composite code CHAR is being re-coded using the explicit finite difference
method on the CM5 Massively Parallel Machine that MIT has acquired recently. After CHAR-
CM5 is completed, the new thermodynamically-based material and reaction models will be
included into the code to perform parametric studies.
References
[1] Sullivan, R.M., "On the Constitutive Relations for the High-Temperature, Nonlinear
Expansion of Polymeric Composites," AMD-Vol. 159, Mechanics of Composites, Materials
Nonlinear Effects, Editor: M.W. Hyer, 1993, pp. 331-342.
[2] Biot, M.A., "New Fundamental Concepts and Results in Thermodynamics with Chemical
Application," Chemical Physics 22, 1977, pp. 183-198.
[3] Biot, M.A., "Variational-Lagrangian Irreversible Thermodynamics of Initially-Stressed Solids
with Thermomolecular Diffusion and Chemical Reactions," Journal of Mechanics and Physics of
Solids, 1977, Vol. 25, pp. 289-307.

©.it.
t
Z C_q_a
c_
©
©
C_
C_
©
ov=nl
©
O
2
©
c_
0 ©
oI==_
c_
"C
©
n_
_=_
_b , ° I,==1
1--==1 _
v.===l
ov==l
Z:
N
-,==4
r_
0 o
t_
0
o
0
°_

_ C O
_ O
_rj3
°l-I _
cr_ =
,°.
,p.,.,.,,(
• • •
)Q
r.tJ
Z
THERMOCHEMICAL MODEL
Heat Flux
____Pressure
Gas Flow
Insulated, Impermeable Base
Control
Volume
_ _ :_
Pressure Pb
Normal Traction T b
3
Shear Tractions
• Tb. Tb
1 _ 2
om ate
Fixed Base
IIII
3
e_
o,
iii
e_
e_
,=l
e_
cT_
l
I
Im,f.
c-"
<
c,_
me
e_
Stress Ratio, Rz
N
| • " I
Moisture Loss
Char Volume, vc MCo- MC (percent)
0 0
0
Pressure Difference
AP=P.pb /MPal
O_G_NAL PAON_m
o_ _o_ _.r_
o _
0l
I !
.0
olmi
ovm,I
÷
...I"
0
"4-
oU
r _
|
oml
I
ollnl
r_
r_
¢;
,dm,b
+ r_
0 "_
._ °-
I I
O0
0
,q)==m
e_
o
oll=l
_ 0
lm_ o_lt
C/)
0
i) vml
_mm(
• )=lnl
o
oull
0
ov_l
©
©
c_
cJ_
c_
r_
IIII II
II II II
s0
0o
,., 0
I I I I I
0 0 0 0 0 0
cO o3 t_3 o3 od o_1
©0 _
ovn(
C_
_ II II
c_
_ II II il
IN
A
w
o
I I I I l
©
• _=.=I
_'_
• _==.(
c_
>
O_Jl_
I==-.(
.vmi
,._
>
ov_i
O
_:_
I I I
0 r_
°_-._
> o
II II II
= _ , II
°_
©
@
emal
=
em
em
=
i.
iI
0
0
0
<l
<IO
<le
li il il
<tO
_e
I
0
i i i i a •
!
0
I I 1
I
0
I | •
!
0
0
o
0
0
m
d
0
0
0
0
"G
0
dl_j *
A
V
0
Q
Q
e,l _ e,i , I_
II, II II ' 0_1
a * ¢ • • I | * | • , |
I I I I I
0 O 0 0 0
¢D ¢_I 0 SO
¢0 ¢0 ¢0 ¢0 04
0
0
0
0
0 o
o_,,_
• _--,(
II II II
0
>
C_
©
E
! I I
I
II II II , -_
• ) _ © II II II II _ ._
©
om
0 o
0
O
[]
0
Im||
0
0
0
[]
0
[]
0
II II II
• 0 0
0
0
aa., |a||
! I
(u,a]_T)0_ss0_
0
0
U')
0
0
ID
• i i ai 0LO
o _
Ei
o
00
o'>
II IIII
0 n •
t D
0
_O
_O
_i I i ! i
0 o
co qq-
t D
[]
0
0
I
o
t'y
t_
• 0
0
,_ D
O
• O
O
0
[]
0
0
m
_O0
O00
0
0
0
0
0
0
0
0
0
0
0
0
0
ii'||III
0
()I) 0am a0dm0 L
0
0
o
_o _j
o
0
0
o
00
¢o
¢y
o_,,_
r._
0
©
° ,i-=1
0
>
I,,,..
E
II II II
II II II
©
r._
+--+
°_--4
©
0
"+"4
0
O.
em
em
em
I.
I.
"0
0
0
D
0
0
l]
n
Q
l]
c_ d
II II II
eeml eenq .tu_
0 D
Q
0
0
0
_'ll|ll_l|ll;llllll
8
(_dl_)0Jnss0._I
0
0
u
0
0
0
"E
;>
0
o3
__ _1 °
It II II |
___I -
,(3O
,(I
41
0
0 0 0 0 0
_O _ C_l 0 eO
03 03 03 , 03
e,i
,,I,m
0
0
0
0
O0
_D
c_
0
_J
_ R
_J
"0
R _
,w,a _
• v._ olml
i !
_J
, II
"" II
" IIt_m_
_._ C_ °w_
[..
llll, j
0
cO
C_
i
v
0
' 0
0
,d •
d •
I
0
CD
t_
4
i •
Iii IBI ill ||l
I I I
0 0 0
()I) o,_Jodmo±
00
I
0
I I i
i"
la
C
c
&
-i
C
c
c
0
0¢M
O;O
_ _ •
IIIi ll*l Ilia
I I I
i i I i
C
U_
C%:
C
T"
C
C
0 c
0
ca_
oV_
ALTERNATE MATERIAL DESIGNS
MULTIPLE MATERIALS
Design Parameters Constrai_uts Problem
Material Choice
(Two or more)
Available Materials
Compatibility
Joining Techniques
T _
\
Stress _k
Stress Concentrations
Weight
Expense
Z
v
COMPOSITES
Design Parameters Constraints •Problems
Constituents
Volume Fractions
Geometry
T_
Available Materials
Compatibility
Processing Techniques
Spatial Uniformity
3rd Dimension
\
Stress
z
v
FGM MATERIAL DESIGNS
Hot Environment
Cool Interior
,,,,,_Mechanica l
Loading
Design Parameters Constraints Problems
Constituents
Volume Fractions
Geometry
ALL FUNCTIONS
OF POSITION
Available Materials
Compatibility
PROCESSING
TBD
T Stress
Z
v
@DESIGNING WITH FGM
FGM frees up the spatial distribution of material properties as design
parameters
This is a key advantage in problems with multiple functional
requirements
EXAMPLE
Hot Environment
Cool Interior
I I _Mechanicalz Loading
TRADITIONAL MATERIAL CHOICE
Desi_;n Parameters Constraints Problems
Material Choice Available Materials All props set by single
choice
May be no sol_. tion
T Stress
z
v
INTEGRATED FGM DESIGN
TRADITIONAL MATERIAL SELECTION PROCESS
|1
NEW MATERIAL STRUCTURAL
DEVELOPMENT _ DESIGN AND
PICK MATERIAL
i. SELECTION
• I
NEEDS DRIVE NEW DEVELOPMENT
TIME CONSTANT - 10 YEARS
Decoupled material and structural design
Very long time before new materials are ready for application
INTEGRATED FGM DESIGN
Fully integrated design, and close cooperation between designers
analysts, and processors, critical for rapid exploitation of FGM
NEEDS
DRIVE
NEW
DEVELOPMENT
T = YEARS
NEW PROCESS
DEVELOPMENT
PROCESS
MODIFICATION
INTEGRATED
STRUCTURAL AND
MATERIAL DESIGN
T=0
CLOSE
COOPERATION
T = MONTHS
Parallels major initiative in the MIT Aeronautics and Astronautics
Department in Engineered Materials
@
Integration of material design into aerospace structural engine ,ring
Research and educational initiatives
TOOLS FOR INTEGRATED DESIGN
PROCESS MODELING
Given process parameters, what is the microstructure as a function of
position?
MICROMECHANICS
Given constituent properties, volume fractions, architecture._ and
microstructures, what are the local bulk properties?
GRADIENT STRUCTURE ANALYSIS
Given loca] bulk properties as functions of position, what ar the
distributions of temperature, stresses, etc., also as functions f
position?
GLOBAL STRUCTURAL ANALYSIS
What is the response of the entire structure?
t793"C
/ I 093"C
/ 962"C" 871"C .-
/ / t ..... . 1454
_2 .or _ 1 982'C "C '
Hot Envh.onaunt
4J,--
_MechJm_l
Loadm 8
Cool Interior
All these analyses must be coupled
@EXAMPLE DESIGN ANALYSIS
Computer code adapted from charring ablator code CHAR
Coupled thermal, porous flow, chemical reaction, and thermo-poro-
elastic structural solutions
Transient solutions for arbitrary thermal BCs, and several stru ctural
cases (coatings, plates)
Simple FGM input
Crude micromechanics
Limited material failure and damage modeling capabilities
Shear __Force
Heat Flux + Pressure
Flow throu_: _
porous media
and/or holes
Cooling gas
User-Specified Graded Material
EXAMPLE CASE
Environment = 500°C
Cooling gas = O°C
No Transpiration
Silica Copper with Various Gradients
¢d3
.o
o
L
1.00
0.75.-
0.50-
0.25
0.00 O,(all Cu) ,'""C::::"_'_
0
c_ _ c5
z (m)
EXAMPLE CASE RESULTS
400
_ _OOl1,,....\ \
E
lo 4-,,
z(m)
2 .._: ':.%:
•_:i',:_....':.?
_.,,.._.., :,';._ .'.,,.:,.,,...:...._.
z(m)
SUMMARY AND CHARGE
To apply FGM concepts to practical design problems as quickly as possible
• Bottleneck disdplines must be identified and worked on
° Existing processing, analysis and design capabilities must be _ tegrated
for FGM application
It is our hope that this workshop will
• Identify what can and cannot be done with existing technique
• Aid in the integration of existing knowledge
• Identify critical areas for research and development
o_,,q
• v,,,_
Z0
0
.v.._
cD
©
c_
Imm.O
;>
• v,-,I
r_
.v,ml
0
O'
"ml
_mb
.lml
r_
ov,-t
0
r_
C_
ZZ



Modeling of outgassing and matrix decomposition in carbon-phenolic composites

Abstract

Similar works

Full text

Available Versions

NASA Technical Reports Server