ABSTRACT Superconducting magnets used in accelerators such as the Superconducting Super Collider @SC) are exposed to fast neutron and gamma irradiation. Some of the components used in the SSC cryostat are fabricated from organic materials with low radiation resistance. The slide bearing material presently supporting the magnet assembly contains Teflon and must be replaced with a material of improved radiation resistance. A group of sliding materials, most of which have suitable radiation resistance, were tested under conditions of pressure, temperature, velocity, and vacuum typically encountered in normal cryostat operation. As this was a preliminary screening test, the samples were only cooled to liquid nitrogen temperature. The group of materials tested consists of composites, coated base metals, and ceramics. The criteria was to maintain a low coefficient of friction throughout the experiment in spite of changes in temperature and vacuum. Subsequent tests will expose finalist materials to fast neutron irradiation at liquid helium temperatures. This paper describes the experimental setup and presents data of the friction coefficient measurements taken for the various samples

A Lipski

M Ruschman

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Fermi National Accelerator Laboratory 
FERiWIAB-Conf-9244 
Friction and Wear of Radiation Resistant 
Composites, Coatings and Ceramics in 
Vacuum and Low Temperature Environment 
A. Lipski and M. Ruschman 
Fermi National Accelerator Laboratory 
P.O. Box 500, Batauia, Illinois 60510 
April 1992 
Presented at the CECIICMC Conference, Huntsville, Alabama, June 11-14, 1991. 
@ Operated by Universities Research Assocla6on Inc. u&rContrac, No. DE-AC%-+76CHOX03 ,-vim tw United States Deparhentof Energy 
. ILhsdimer 
This report was prepared as an account of work sponsored by an agency of the United States 
Gouernment. Neither the United States Government nor any agency thereof nor any of 
their employees, makes any warranty, express or implied, or assumes any legal liability or 
responsibility for the accuracy, completeness, or usefulness of any information, apparatus, 
product, or process disclosed, or represents that its use would not infringe privately owned 
rights. Reference herein to any specific commercial product, process, or service by trade 
name, trademark, manufacturer, or otherwise, does not necessarily constitute or imply its 
endorsement, recommendation, or favoring by the United States Government or any 
agency thereof. The views and opinions of authors expressed herein do not necessarily state 
or reflect those of the United States Government or any agency thereof 
FRICTION AND WEAR OF RADIATION RESISTANT COMPOSITES, 
COATINGS AND CERAMICS IN VACUUM AND LOW TEMPERATURE 
ENVIRONMENT 
A. Lipski and M. Ruschman 
Fermi National Accelerator Lahoratoly* 
Batavia, Illinois 
ABSTRACT 
Superconducting magnets used in accelerators such as the Superconducting Super 
Collider @SC) are exposed to fast neutron and gamma irradiation. Some of the components 
used in the SSC cryostat are fabricated from organic materials with low radiation resistance. 
The slide bearing material presently supporting the magnet assembly contains Teflon and 
must be replaced with a material of improved radiation resistance. A group of sliding 
materials, most of which have suitable radiation resistance, were tested under conditions of 
pressure, temperature, velocity, and vacuum typically encountered in normal cryostat 
operation. As this was a preliminary screening test, the samples were only cooled to liquid 
nitrogen temperature. The group of materials tested consists of composites, coated base metals, 
and ceramics. The criteria was to maintain a low coefficient of friction throughout the 
experiment in spite of changes in temperature and vacuum. Subsequent tests will expose 
finalist materials to fast neutron irradiation at liquid helium temperatures. This paper 
describes the experimental setup and presents data of the friction coefficient measurements 
taken for the various samples. 
INTRODUCTION 
The effect of radiation on materials has been of great concern to the designers of high- 
energy accelerators. The subject of high-energy radiation damage to polymers used in 
accelerators has been the subject of several studies and publications. It has been pointed outI 
that the Teflonctrade name used by DuPont) resin, used in the present cold mass slide 
material, could be affected by the high levels of radiation found in the SSC dipole magnets. 
The cold mass assembly is supported and laterally restrained by cradle assemblies at 
five locations along its length. Aside from the center cradle which is fixed, the other four 
cradles allow for thermal expansion or contraction of the cold mass along its axis, as shown in 
figure 1. The cold mass assembly slides on four bearing pads mounted in the sliding cradle as 
illustrated in figure 2. The present bearing pads are DU (trade name used by Garlock 
Bearing) bearings which contain Teflon (PTFE), impregnated in the porous bronze as well as 
in the form of an overlay. 
This paper describes the work performed to select one or more materials with 
comparably low coefficients of friction, yet better radiation resistance properties, with which to 
replace the DU bearing material. 
SLIDING CRADLE (1 OF 4) 
COLD MASS ASSEMBLY 
FIXED CENTER CRADLE 
ANCHOR TIE BAR (1 OF 4) 
SUPPORT POST (1 OF 5) 
bOK SHIELD 20K SHIELD’ 
Fig. 1. SW 5Omm Dipole Cryostat Suspension System 
UPPER CRADLE BAND 
BEARING PADS ARE ATTACHED 
TO THE CRADLE WITH DOUBLE 
3.05 THICK 
SIDED ADHESIVE TAPE. 
BEARING PAD 
Fig. 2. Cradle Assembly and Bearing Pad Detail 
MATERIAL SELECTION 
The primary requirements for selecting the slide material were: 
l Maintain friction coefficient of 0.20 to 0.22 at operating conditions. 
l Maintain performance capabilities in radiation levels exceeding 3 x 103 gray over a 20 
year period. 
In addition the following operating conditions will have to be met: 
l Temperature: Operating temperature of approximately 4 K; storage temperature of 
approximately 340 K 
l Vacuum: 10e7 Torr at the operating temperature 
l Pressure: 4.14 MPa - dynamic at the operating temperature. 
8.28 MPa - static at 320 K 
l Humidity: 0% at the operating temperature. 
Other performance criteria which have been taken into consideration are aging and wear. 
The slide samples are tested for approximately 900 cycles of duty. A cycle denotes expansion 
and contraction of a magnet (ti.5 cm). Over a 24 hour period the magnet will contract 2.5 cm 
when cooled from room to operating temperatures. It is also assumed that the slide material 
will be exposed to air after being irradiated several times during the course of its lifetime. 
The selected materials can be divided into three groups: 
ceramics, as shown in Table 1. 
coatings (of metals). composites and 
EXPERIMENTAL SETUP 
The test setup was made to simulate the actual conditions of the slides in the magnet. However, 
since this is a preliminary test, several variations from the actual situation were adopted. (See 
material selection) 
l The low temperature is approximately 80 K and the vacuum is 10e5 Torr. 
l The support posts are made of solid stainless steel to minimize post deflection 
l The loading pressure is the equivalent to that of a dynamic loading during operating 
conditions. (See material selection) 
Table 1. Sliding Test Samples 
Coating/Metal 
CoNiInMoQ/Inconel 718 
Graphite (embedded) / 
bronze - copper 
Everlube 86QB16 SS 
Ti-TiN/316 SS 
WS2i316 SS 
Composite 
Vespel SP-1 
Vespel SP-3 
APC-WAS4 (PEEK) 
(0” fiber orientation) 
Torlon 4301 
PEEK/carbon (short fiber) 
Ceramic 
.‘iIP&,+&@ 
(Sic - continuous fiber) 
Glass bonded Mica 
The samples were secured on the stationary portion of the sliding apparatus. All samples were 
tested sliding against 316 stainless steel plates with a surface finish of 0.50 pm to simulate the 
cold mass skin. Each set of samples was fitted with a new set of stainless steel plates. The 
stainless steel plates were mounted on to the moving portion of the sliding apparatus. The 
complete sliding apparatus was placed inside a vacuum vessel as shown in figure 3. 
In order to maintain close simulation between the test and the actual magnet performance the 
following system requirements were imposed: 
. Stroke = * 2.54 cm 
. Stroke velocity = .0025 m/see 
. Total contact area = 12.9 cm2 
. Dead load weight = 485 kg 
The friction force was measured by a load cell in line with the actuation system. The load cell 
readings and corresponding temperature readings were recorded by a computerized data 
acquisition system. The coefficient of friction (COF) was calculated by dividing the friction 
force by the normal force (dead weight). 
The actuation system included a closed loop controller which produced a constant speed 
reciprocating motion, thus eliminating inertia from affecting the load cell measurements. 
Data for dynamic COF is obtained from 900 cycles as shown in Table 2. The force data for the 
dynamic COF (coefficient of friction) was generated by taking an average of six readings per 
cycle. In addition, measurements of static coefficient of friction (force to slip) as well are 
taken at six separate instances as described in Table 2. The static COF was measured for a 
single cycle over a length of 1.5mm traveling at a velocity of .025mm/sec. 
RESULTS AND DISCUSSION 
As can be seen from Table 3 as well as from figures 4 and 5, three coatings sucessfully 
completed the test. However the COF of the graphite (embedded) / bronze-copper was the lowest 
within the required range. Its COF never exceeded 0.20 throughout the test. The embedded 
solid lubricant bearing is composed of a solid lubricant bearing (in a plug form) and base 
metal. The sliding medium consists of a pattern of embedment and a surface lubrication 
which is used for startup.(See figure 8) The other two coatings which met the test requirements 
were the Everlube 860 / 316 SS and the CuNiInMoS2 / Inconel718. Over all, the test results show 
that the COF of the coating group is lower than that of the composite group. The APC-2 / AS4 (0” 
Table 2. Sliding Test Sequence 
Cycle W 
l-300 
3Do-600 
6DD-900 
F 
1 
2 
3 
300 
6m 
933 
900 
Pressure 
10s 
105-103 
103 
760 
103 
10s 
lti 
103 
103 
103 
Temperature 
(IO 
al 
warm-up (80 _ 285) 
285 
!285 
285 
83 
80 
285 
285 
!a5 
&-ST SPECIMENS 
SECTION A-A 
v- 
A 
Fig. 3. Sliding Test Apparatus 
fiber orientation) had the lowest COF among the composites group. As evident in the 
comparison plots (figures 6 and ‘7) the COF increased when temperatures increased from EoK to 
room temperature for all samples. However there is no uniform pattern evidenced in the 
behavior of the various materials at room temperatures. While the COF for composites 
changed erratically over a wide range of values, that of the coated metals maintained a more 
settled nature with respect to temperature changes and number of cycles. 
The materials in the tests which were terminated failed by exceeding the upper limit of COF. 
(upper limit was set at 1890 N) In the composite group, the materials which failed exhibit stick - 
slip behavior and the high COF seems to result predominantly due to adhesive frictional 
interaction between the stainless steel and the composite material. 
Graphite (embedded)/bronze-copper is the only sample of which the COF continued to increase 
during the last portion of the test. In comparison the COF of all other samples dropped or 
stabilized. 
Table 3. Summary of Test Results 
DU (Bronze + Teflon) 
~m~o~~~ 
Vessel SP-1 
Vespel SP-3 
APc-2/As4 (O%ber 
orientation)) 
Torlon 4301 
PEEK&&on 
- 
CuNiInMoS2 I IIICOIUI 
718 
Graphite (embedded) 
Bronze-copper 
Everluhe 860 /316 SS 
Ti-TiNf316SS 
WSo / 316 SS 
Friction Coeffioient 
O-300 
cycles 
.16 
.37 
.18 
.13 
34 
23 
.09 
.08 
.08 
A2 
.40 
300-600 
z!$L 
600-900 
CYCISS 
.12 
.18 - .40 
3.3 
28 
37 
.14 
23 
38 
22 .16 
.15 .19 
21 21 
Remarks 
rest terminated after 50 cycles B 80K 
Pest terminated after 400 cycles @ 2001 
r-t terminated after 25 C,‘Ch 9 80K 
Pest terminated after 25 cycles S 8OK 
0.40 
0.35 
E 0.30 
‘L= 
.$ 0.25 
2 0.20 
6 
g 0.15 
: 
0 0.10 
0.05 
0.00 
Cycle # Pressurqtwr) 
QQCb3OQ 10-s 
301-600 <l O-3 
601-900 10-J 
0 CuNiln/MoS2 / lnconel 718 
0 Graphite/Bronze-Copper 
A Everlube 860 / 316 SS - 
P DU Material 
0 100 200 300 400 500 600 700 800 900 
Cycle Number 
Fig. 6. Comparison Plots of COF for Coated Metals 
0.40 
0.35 
.b 0.30 
t; 
‘: 0.25 
: 0.20 
.$ 
‘E 0.1 5 
s 
” 0.10 
0.05 
0.00 - 
0 
ooo-300 10-D 
0 Veapel SP-3 
0 WC-2/AS4 
a Tarlan 4301 
Tot -60a (1 o-3 
v PEEK/Carbon 
601-900 10-S I I 1 
100 200 300 400 500 600 700 
Cycle Number 
Fig. 7. Comparison Plot3 of COF for Composites 
800 900 
.5 X 45’ ALL AROUND 
P3 SOLID LUBRICANT PLUGS 
\\ 17 PLACES 
.5 x 45’ 
ALL AROUND 
Fig. 6. Graphite (embedded)lBronze-Copper (Courtesy - Oiles America Corp.) 
CONCLUSION 
This work concentrated on the selection of materials which have known good resistance to 
radiation yet unknown COF at vacuum and low temperatures. The test attempted to simulate 
the actual conditions occurring inside a dipole cryostat during cool down and warm up. Over 
all it was found that coatings of metals performed better than bearings made of solid 
composites. The dynamic COF increased in direct proportion to the rise in temperature and 
then either decreased or stabilized (in most cases) during the last portion of the test at room 
temperature. 
on the COF. 
In most of the cases the number of cycles did not seem to have an adverse effect 
The COF of the coatings appear to he more uniform than that of the various 
composite materials. Although three materials met the required COF of 0.20 - 0.22, the 
investigation for a replacement material for the DU bearings is far from complete. The 
materials which took part in this test so far represent only a fraction of a more comprehensive 
list of coatings and composites which need to be evaluated. Ceramic materials have the 
potential to be good candidates, thus further evaluation and testing are recommended. 
In addition, further testing and evaluation is required with fmalist material such as graphite 
(embeddedfironze-copper or the Everlube 860/316 SS. Prior to selecting a replacement 
material for the DU the following subjects should bs investigated. 
l Long term effects of high vacuum (lo-’ Torr) on the material and its compatibility in 
the cryostat environment. 
l Bearing ability to perform adequately a&r being irradiated as well as exposed to air. 
l Wear mechanism. 
l Behavior under multiple thermal cycles. 
ACKNOWLEDGEMENTS 
The work as presented was performed at Fermi National Accelerator Laboratory 
which is operated hy Universities Research Association, Inc. under contract with the U.& 
Department of Energy. 
REFERENCES 
1. DuPont, ‘Radiation Tolerance of Teflon Resins,” January - February 1969 issue of The 
Journal of Teflon. 


Friction and Wear of Radiation Resistant Composites, Coatings and Ceramics in Vacuum and Low Temperature Environment

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Friction and Wear of Radiation Resistant Composites, Coatings and Ceramics in Vacuum and Low Temperature Environment

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