diff --git "a/data/AMS/ams_data-400-0-50.json" "b/data/AMS/ams_data-400-0-50.json"
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+++ "b/data/AMS/ams_data-400-0-50.json"
@@ -0,0 +1,53 @@
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+ "viz_data": "{\"columns\":[\"id\",\"x\",\"y\",\"document\",\"document_cleaned\",\"size\",\"category\"],\"index\":[0,1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40,41,42,43,44,45,46,47,48,49],\"data\":[[\"009bc76a-bd43-11ee-801f-bae7cd9d315f\",5.689907074,6.0673141479,\"181 Developmental Testing of Electric Thr ust Vector Control Systems for Manned Launch Vehicle Applications \\n\\nLisa B. Bates* and David T. Young** \\n\\nAbstract \\n\\nThis paper describes recent developmental testing to verify the integration of a developmental electromechanical actuator (EMA) with high rate lithium ion batteries and a cross platform extensible controller. Testing was performed at the Thrust Vector Control Research, Development and Qualification Laboratory at the NASA George C. Marshall Space Flight Center. Electric Thrust Vector Control (ETVC) systems like the EMA may significantly reduce recurring launch costs and complexity compared to heritage systems. Electric actuator mechanisms and control requirements across dissimilar platforms are also discussed with a focus on the similarities leveraged and differences overcome by the cross platform extensible common controller architecture. Introduction{'source': 'AMS_2012.pdf', 'page': 195}\",\"181 Developmental Testing of Electric Thr ust Vector Control Systems for
Manned Launch Vehicle Applications Lisa B. Bates* and David T. Young**
Abstract This paper describes recent developmental testing to verify the
integration of a developmental electromechanical actuator (EMA) with high rate
lithium ion batteries and a cross platform extensible controller. Testing was
performed at the Thrust Vector Control Research, Development and Qualification
Laboratory at the NASA George C. Marshall Space Flight Center. Electric Thrust
Vector Control (ETVC) systems like the EMA may significantly reduce recurring
launch costs and complexity compared to heritage systems. Electric actuator
mechanisms and control requirements across dissimilar platforms are also
discussed with a focus on the similarities leveraged and differences overcome by
the cross platform extensible common controller architecture.
Introduction{'source': 'AMS_2012.pdf', 'page': 195}\",3,\"Chunks\"],[\"0149266c-bd43-11ee-801f-bae7cd9d315f\",3.2121088505,7.6814665794,\"Figure 15. Stroke Testing of the final guide design under high loading conditions (load is equivalent to 3.2-g radial and 5.4 times the maximum flight moment){'source': 'AMS_2012.pdf', 'page': 265}\",\"Figure 15. Stroke Testing of the final guide design under high loading
conditions (load is equivalent to 3.2-g radial and 5.4 times the maximum
flight moment){'source': 'AMS_2012.pdf', 'page': 265}\",3,\"Chunks\"],[\"03ae7b3c-bd43-11ee-801f-bae7cd9d315f\",7.4775462151,8.7771959305,\"from pushing the the green Drive Pin out of the Toroidal Bushing. When the ERM releases the central rotor, the drive spring is free to expand and pushes the Drive Pin out of the Toroidal Bushing and into a guide hole in the anchor fitting. To reset the actuator, the the Drive Pin is manually pulled back through the Toroidal Bushing (v ia the Reset Linkage a nd the Rotor Arm) and connected to the reset ERM. The titanium Anchor FIttings and Toroidal Bushings had a Tiodize\\u00ae type II (Teflon\\u00ae impregnated) finish. The Drive Pins are made of aluminum bronze, CDA 63020 per AMS 4590B. A light film of Braycote{'source': 'AMS_2012.pdf', 'page': 408}\",\"from pushing the the green Drive Pin out of the Toroidal Bushing. When the ERM
releases the central rotor, the drive spring is free to expand and pushes the
Drive Pin out of the Toroidal Bushing and into a guide hole in the anchor
fitting. To reset the actuator, the the Drive Pin is manually pulled back
through the Toroidal Bushing (v ia the Reset Linkage a nd the Rotor Arm) and
connected to the reset ERM. The titanium Anchor FIttings and Toroidal Bushings
had a Tiodize\\u00ae type II (Teflon\\u00ae impregnated) finish. The Drive Pins are made of
aluminum bronze, CDA 63020 per AMS 4590B. A light film of Braycote{'source':
'AMS_2012.pdf', 'page': 408}\",3,\"Chunks\"],[\"05928484-bd43-11ee-801f-bae7cd9d315f\",4.4773106575,10.9182357788,\"the first seque nce, were perform ed a nd th e mech anism was pla ced into vacuum cyclin g. Tabl e 3 shows number of op eration s at st eps d uring the second lifetime simulatio n seque nce. Table 3. HCM Life-T est Second Seq uence \\n\\nOper ation Seque nce 2 Ops Break-in CW Spin 56,200 Pre-Lifetest Fu nctional Testing 138,180 Vibration Test 138,180 Thermal F unctional Testing 704,340 Software Ve rification 727,570 Vacuum Ope ration 3,573,250 Post-Lifetest Fun ctional Testing 3,691,832 Additional Repea tability Testing 4,276,882 \\n\\nFigure 13a & 13b. Proto-Qualifica tion HCM Conta mination: L ocking Fea ture on Mech anism Scre w (left) and an Alum inum and Ch romate Par ticle Remov ed from the Bearing (righ t) 23{'source': 'AMS_2004.pdf', 'page': 37}\",\"the first seque nce, were perform ed a nd th e mech anism was pla ced into
vacuum cyclin g. Tabl e 3 shows number of op eration s at st eps d uring the
second lifetime simulatio n seque nce. Table 3. HCM Life-T est Second Seq
uence Oper ation Seque nce 2 Ops Break-in CW Spin 56,200 Pre-Lifetest Fu
nctional Testing 138,180 Vibration Test 138,180 Thermal F unctional Testing
704,340 Software Ve rification 727,570 Vacuum Ope ration 3,573,250 Post-
Lifetest Fun ctional Testing 3,691,832 Additional Repea tability Testing
4,276,882 Figure 13a & 13b. Proto-Qualifica tion HCM Conta
mination: L ocking Fea ture on Mech anism Scre w (left) and an Alum inum and
Ch romate Par ticle Remov ed from the Bearing (righ t) 23{'source':
'AMS_2004.pdf', 'page': 37}\",3,\"Chunks\"],[\"06e5a7c6-bd43-11ee-801f-bae7cd9d315f\",6.7834515572,9.8055076599,\"high fo rces a pplied to the l ocking pins by the latc h mechanism. De sign changes to the pl ate were ma de to increa se stiffness at the l ocking pi n mounting p oints, and thi s chang e elimin ated plate b endin g as a probl em. \\n\\nLatch Point E ngag ement Becau se of manufa cturing tolerances and th e curved m otion of the spring beams, some dimen sional allowan ce must be mad e at the beam-t o-latch pin co ntact point. In the initial desig n, the allowa nce wa s gene rous, and the holding ability of the l atch in the Z di rection was augmente d by frictional forces. In fact, mating surfaces were tex tured by grit blastin g in order to enhance fri ction. It was fou nd in testing that texturing a ctually aggravat ed gallin g of the mating surface s, and th at desig n feat ure was delet ed. Smooth surfa ces were use d inste ad, with su rface treatment for hardening. Tolera nces were tightene d, and it wa s then po ssible to redu ce th e dimen sion of the pocket in the spri ng beam in whi ch the lo cking pin se ats. The upp er and lowe r sho ulders of the pocket offer pos itive re straint of the locking pin which is n ot depe ndent o n friction. 105{'source': 'AMS_2004.pdf', 'page': 119}\",\"high fo rces a pplied to the l ocking pins by the latc h mechanism. De sign
changes to the pl ate were ma de to increa se stiffness at the l ocking pi n
mounting p oints, and thi s chang e elimin ated plate b endin g as a probl em.
Latch Point E ngag ement Becau se of manufa cturing tolerances and th e curved
m otion of the spring beams, some dimen sional allowan ce must be mad e at
the beam-t o-latch pin co ntact point. In the initial desig n, the allowa nce wa
s gene rous, and the holding ability of the l atch in the Z di rection was
augmente d by frictional forces. In fact, mating surfaces were tex tured by
grit blastin g in order to enhance fri ction. It was fou nd in testing that
texturing a ctually aggravat ed gallin g of the mating surface s, and th at
desig n feat ure was delet ed. Smooth surfa ces were use d inste ad, with su
rface treatment for hardening. Tolera nces were tightene d, and it wa s then po
ssible to redu ce th e dimen sion of the pocket in the spri ng beam in whi ch
the lo cking pin se ats. The upp er and lowe r sho ulders of the pocket offer
pos itive re straint of the locking pin which is n ot depe ndent o n friction.
105{'source': 'AMS_2004.pdf', 'page': 119}\",3,\"Chunks\"],[\"06e5a8f2-bd43-11ee-801f-bae7cd9d315f\",6.1723618507,10.4475269318,\"Coordinate 3, Cran kshaft L oads (Fig. 4) The inte rmediate sh aft driv es a cran kshaft with an gular Coordinate \\u03b83, having two b earing drag to rques T31B and T 32B. These two drag torques could be referenced directly to the drive shaft, skipping the intermediate shaft ( \\u03b82), by their di splacement ratio t o the drive shaft (\\u03b83\\/\\u03b81). However, this task is more system aticall y organized by first collecting the loads from th e crank and pisto n, and th en referencing their sum from the crankshaft ( \\u03b83) to the driveshaft ( \\u03b81). \\n\\nCoordinates 4, 5, and 6, Linka ge Bea ring Load s and Piston Loa ds (Fig. 4) Although th e friction to rque from th e inte rmedi ate crank bearing T4B also acts directly on the crankshaft, this be aring\\u2019s displ acemen t, \\u03a64, is relative to its two mating crank linkages. This relative displacement, \\u03a64, is gre ater that the displa cement \\u03b83 of the lower link relative to the cran kshaft, in the crank position shown. \\n\\n\\u03a64 = \\u03b83 + \\u03b85 (7) \\n\\nThe fri ction t orque of this cra nk bearing acts on both the upp er crank and th e lower crank. Thu s, the{'source': 'AMS_2004.pdf', 'page': 127}\",\"Coordinate 3, Cran kshaft L oads (Fig. 4) The inte rmediate sh aft driv es a
cran kshaft with an gular Coordinate \\u03b83, having two b earing drag to rques
T31B and T 32B. These two drag torques could be referenced directly to the drive
shaft, skipping the intermediate shaft ( \\u03b82), by their di splacement ratio t o
the drive shaft (\\u03b83\\/\\u03b81). However, this task is more system aticall y
organized by first collecting the loads from th e crank and pisto n, and th en
referencing their sum from the crankshaft ( \\u03b83) to the driveshaft ( \\u03b81).
Coordinates 4, 5, and 6, Linka ge Bea ring Load s and Piston Loa ds (Fig. 4)
Although th e friction to rque from th e inte rmedi ate crank bearing T4B also
acts directly on the crankshaft, this be aring\\u2019s displ acemen t, \\u03a64, is
relative to its two mating crank linkages. This relative displacement, \\u03a64, is
gre ater that the displa cement \\u03b83 of the lower link relative to the cran
kshaft, in the crank position shown. \\u03a64 = \\u03b83 + \\u03b85 (7) The fri ction
t orque of this cra nk bearing acts on both the upp er crank and th e lower
crank. Thu s, the{'source': 'AMS_2004.pdf', 'page': 127}\",3,\"Chunks\"],[\"0784b726-bd43-11ee-801f-bae7cd9d315f\",6.8542079926,9.7067556381,\"\\u2022 Latch 5: Dim ensions: 102 mm (4\\u201d)L X 1 02mm (4 \\u201d)W X 191mm (7. 5\\u201d)H Mass = 1.4 kg Material s for Major Comp onents \\u2022 ACME Sc rew: CRES 17-4PH \\u2022 Barden 107H Ball B earings: CRES 4 40C \\u2022 Latch Housing: Al 7075-T7 3 \\n\\n133{'source': 'AMS_2004.pdf', 'page': 147}\",\"\\u2022 Latch 5: Dim ensions: 102 mm (4\\u201d)L X 1 02mm (4 \\u201d)W X 191mm (7. 5\\u201d)H
Mass = 1.4 kg Material s for Major Comp onents \\u2022 ACME Sc rew: CRES 17-4PH
\\u2022 Barden 107H Ball B earings: CRES 4 40C \\u2022 Latch Housing: Al 7075-T7 3
133{'source': 'AMS_2004.pdf', 'page': 147}\",3,\"Chunks\"],[\"08323004-bd43-11ee-801f-bae7cd9d315f\",4.3582348824,10.8563108444,\"material s. Fi nally, the a bility to weld titanium a llowed the suspen sion stru ctural comp onents to b e optimize d for stren gth and flexibility. Eight of the ten suspension tube mem bers we re welde d. The de sire to increa se the Ti-6AL-4V from the anneale d to a solution treate d and aged (STA) state was resisted. While th e ST A pro cess would incre ase the strength of the titanium from 90 0 MPa (13 0 ksi) t o 1100 MPa (160 ksi), the weld seam s would rem ain in the anne aled co ndition, creating a n obvious a nd unacce ptable weak li nk that could only be mitigated if the STA pr ocess was performe d after welded. T he possibility that the weld me mbers would distort signi ficantly durin g the STA pro cess due to th eir thin walle d constructio n was deem ed too risky to accept. Therefore, all the su spension tub e membe rs were kept in their ann ealed condition. \\n\\nStructu ral Me mber F abrication The de sire to cre ate a su spen sion that efficiently ab sorbs e nergy leads to st ructural m embers th at are thin wall ed box beam s. A b ox beam design is a m ass efficient ge ometry for compone nts subjected to both bendi ng and torsio nal loads. The beams are also tapered wherever po ssible t o incre ase m ass saving s.{'source': 'AMS_2004.pdf', 'page': 203}\",\"material s. Fi nally, the a bility to weld titanium a llowed the suspen sion
stru ctural comp onents to b e optimize d for stren gth and flexibility. Eight
of the ten suspension tube mem bers we re welde d. The de sire to increa se the
Ti-6AL-4V from the anneale d to a solution treate d and aged (STA) state was
resisted. While th e ST A pro cess would incre ase the strength of the titanium
from 90 0 MPa (13 0 ksi) t o 1100 MPa (160 ksi), the weld seam s would rem ain
in the anne aled co ndition, creating a n obvious a nd unacce ptable weak li nk
that could only be mitigated if the STA pr ocess was performe d after welded. T
he possibility that the weld me mbers would distort signi ficantly durin g the
STA pro cess due to th eir thin walle d constructio n was deem ed too risky to
accept. Therefore, all the su spension tub e membe rs were kept in their ann
ealed condition. Structu ral Me mber F abrication The de sire to cre ate a
su spen sion that efficiently ab sorbs e nergy leads to st ructural m embers th
at are thin wall ed box beam s. A b ox beam design is a m ass efficient ge
ometry for compone nts subjected to both bendi ng and torsio nal loads. The
beams are also tapered wherever po ssible t o incre ase m ass saving
s.{'source': 'AMS_2004.pdf', 'page': 203}\",3,\"Chunks\"],[\"0a6ab382-bd43-11ee-801f-bae7cd9d315f\",4.5527009964,11.0192298889,\"The de sign of the butterfly element s that engage a nd become prelo aded ag ainst a rock was a formida ble task. It is necessary to ac tually pr eload the ground structure of the RAT ag ainst the rock, effectively{'source': 'AMS_2004.pdf', 'page': 293}\",\"The de sign of the butterfly element s that engage a nd become prelo aded ag
ainst a rock was a formida ble task. It is necessary to ac tually pr eload the
ground structure of the RAT ag ainst the rock, effectively{'source':
'AMS_2004.pdf', 'page': 293}\",3,\"Chunks\"],[\"0dd5be86-bd43-11ee-801f-bae7cd9d315f\",7.563829422,8.7669439316,\"which the corer would be mounted by reducing mass and required electrical connections. Other design considerations were addressed prior to finalizing the overall concept of the integrated corer design. A decision was made to use a single motor to drive a spring-loaded rotary-percussive cam mechanism, much like the original LSAS drill. Although it was desirable to have the flexibility of independent control over the hammer and rotary functi ons in the manner of the drilling breadboard fixture, the single-motor rotary-percussive mechanism offered simplicity and low mass. An additional motor was incorporated in the design to accomplish core break-off. While it appeared possible to leverage the rotary-percussive motor to achieve this function and save mass, it was much more straightforward to add a second motor. See Figures 6 and 7 for CAD views of the prototype design. NASA\\/CP-2010-216272{'source': 'AMS_2010.pdf', 'page': 38}\",\"which the corer would be mounted by reducing mass and required electrical
connections. Other design considerations were addressed prior to finalizing
the overall concept of the integrated corer design. A decision was made to use
a single motor to drive a spring-loaded rotary-percussive cam mechanism, much
like the original LSAS drill. Although it was desirable to have the flexibility
of independent control over the hammer and rotary functi ons in the manner of
the drilling breadboard fixture, the single-motor rotary-percussive mechanism
offered simplicity and low mass. An additional motor was incorporated in the
design to accomplish core break-off. While it appeared possible to leverage the
rotary-percussive motor to achieve this function and save mass, it was much more
straightforward to add a second motor. See Figures 6 and 7 for CAD views of the
prototype design. NASA\\/CP-2010-216272{'source': 'AMS_2010.pdf', 'page': 38}\",3,\"Chunks\"],[\"0f8d8e8e-bd43-11ee-801f-bae7cd9d315f\",5.6056170464,6.1294298172,\"174 Acknowledgements \\n\\nThe authors and co-authors of this paper express their gratitude to the failure investigation teams. The collaborative efforts of NASA, Boeing, NESC, Battelle, The Aerospace Corporation, L-3 S&N, and independent consultants resulted in comprehensive inve stigations that resulted in identifying the most probable cause for both anomalie s. Accolades we re expressed by Boeing and NASA upper management many times for the team work, leadership and efficiency of the teams identified below: \\n\\n CMG1 Failure Investigation Team NASA\\/CP-2010-216272{'source': 'AMS_2010.pdf', 'page': 190}\",\"174 Acknowledgements The authors and co-authors of this paper express their
gratitude to the failure investigation teams. The collaborative efforts of
NASA, Boeing, NESC, Battelle, The Aerospace Corporation, L-3 S&N, and
independent consultants resulted in comprehensive inve stigations that resulted
in identifying the most probable cause for both anomalie s. Accolades we re
expressed by Boeing and NASA upper management many times for the team work,
leadership and efficiency of the teams identified below: CMG1 Failure
Investigation Team NASA\\/CP-2010-216272{'source': 'AMS_2010.pdf', 'page':
190}\",3,\"Chunks\"],[\"14a7ada0-bd43-11ee-801f-bae7cd9d315f\",7.1994800568,7.1037535667,\"(sync) cable provides redundancy for the dampers and deployment springs, allowing for system deployment in the event of a spring or damper failure. The sync cable also helps maintain the ratio of the two hinge angles to approximately 2:1, as the elbow and shoulder hinges open 180 and 90 degrees respectively during deployment. HGAS contains five mechanisms: three Launch Restraint Mechanisms (LRM\\u2019s), a Lower Boom Assembly (LBA), and the gimbal assembly. The upper boom connects the LBA to the gimbal assembly as shown in Figure 1. The entire HGAS assembly and associated mechanism are supported on an all-aluminum honeycomb plate. The LRMs and hinge line designs were developed from heritage Solar Dynamics Observatory hardware. Launch Restraint Mechanism The HGAS uses three LRMs (known as the A, B, and C devices) to restrain the upper boom and the gimbal assembly to the mounting plate prior to deployment. Each LRM is composed of a latch rod, securing the upper boom or gimbal assembly to two spring-loaded jaws. Each jaw is attached to a non-explosive actuator (NEA). After firing, the NEAs release the latch rods allowing the system to deploy. As designed, LRM C releases first, followed four seconds later by the LRMs A and B simultaneously. Deployment commences once all LRMs are released. Kick-off springs at LRM B and LRM C assist in separating the HGAS assembly from the LRMs. Lower Boom Assembly The LBA, shown in Figure 2, is made up of the two deployment hinges; the elbow hinge and shoulder{'source': 'AMS_2014.pdf', 'page': 62}\",\"(sync) cable provides redundancy for the dampers and deployment springs,
allowing for system deployment in the event of a spring or damper failure. The
sync cable also helps maintain the ratio of the two hinge angles to
approximately 2:1, as the elbow and shoulder hinges open 180 and 90 degrees
respectively during deployment. HGAS contains five mechanisms: three Launch
Restraint Mechanisms (LRM\\u2019s), a Lower Boom Assembly (LBA), and the gimbal
assembly. The upper boom connects the LBA to the gimbal assembly as shown in
Figure 1. The entire HGAS assembly and associated mechanism are supported on an
all-aluminum honeycomb plate. The LRMs and hinge line designs were developed
from heritage Solar Dynamics Observatory hardware. Launch Restraint Mechanism
The HGAS uses three LRMs (known as the A, B, and C devices) to restrain the
upper boom and the gimbal assembly to the mounting plate prior to deployment.
Each LRM is composed of a latch rod, securing the upper boom or gimbal
assembly to two spring-loaded jaws. Each jaw is attached to a non-explosive
actuator (NEA). After firing, the NEAs release the latch rods allowing the
system to deploy. As designed, LRM C releases first, followed four seconds
later by the LRMs A and B simultaneously. Deployment commences once all LRMs are
released. Kick-off springs at LRM B and LRM C assist in separating the HGAS
assembly from the LRMs. Lower Boom Assembly The LBA, shown in Figure 2, is made
up of the two deployment hinges; the elbow hinge and shoulder{'source':
'AMS_2014.pdf', 'page': 62}\",3,\"Chunks\"],[\"157a4896-bd43-11ee-801f-bae7cd9d315f\",6.2788877487,6.0096197128,\"As it could not be actually measured, the stow bias was the least certain value in the ADAMS model. To finalize calibration of the model, the stow bias was iterated until the latch time of both hinges closely matched the latching (i.e. fully deployed) times in the most current g-negated tests. The hinges would not latch at the exact same time due to compliance in the sync cable, allow\\/g76\\/g81\\/g74\\/g3\\/g87\\/g75\\/g72\\/g3\\/g86\\/g80\\/g68\\/g79\\/g79\\/g3\\/g507\\/g3\\/g68\\/g81\\/g74\\/g79\\/g72\\/g3between the two hinges. The final calibration to the ADAMS model was done using the post T-Vac, gnegated, deployment data. The hinge angles of the post T-vac test and the corresponding calibrated ADAMS model predictions are compared in Figure 6. The 3 N (0.7 lbf) of stow bias used to calibrate the model compares favorably to the 2 to 4.4 N (0.5 to 1.0 lbf) stow bias estimated by the test engineers prior to the test. This calibrated model became the baseline ADAMS model. This baseline model, run as a \\u201con-orbit\\u201d (i.e. zero gravity and g-negation system model elements disabled) would be used to predict onorbit performance of the flight configuration HGAS. Potential Deployment Interference After the HGAS subsystem was integrated to the spacecraft, a potential deployment interference issue{'source': 'AMS_2014.pdf', 'page': 68}\",\"As it could not be actually measured, the stow bias was the least certain value
in the ADAMS model. To finalize calibration of the model, the stow bias was
iterated until the latch time of both hinges closely matched the latching (i.e.
fully deployed) times in the most current g-negated tests. The hinges would not
latch at the exact same time due to compliance in the sync cable, allow\\/g76\\/g81\\/
g74\\/g3\\/g87\\/g75\\/g72\\/g3\\/g86\\/g80\\/g68\\/g79\\/g79\\/g3\\/g507\\/g3\\/g68\\/g81\\/g74\\/g79\\/g72\\/g3betwe
en the two hinges. The final calibration to the ADAMS model was done using
the post T-Vac, gnegated, deployment data. The hinge angles of the post T-vac
test and the corresponding calibrated ADAMS model predictions are compared in
Figure 6. The 3 N (0.7 lbf) of stow bias used to calibrate the model compares
favorably to the 2 to 4.4 N (0.5 to 1.0 lbf) stow bias estimated by the test
engineers prior to the test. This calibrated model became the baseline ADAMS
model. This baseline model, run as a \\u201con-orbit\\u201d (i.e. zero gravity and
g-negation system model elements disabled) would be used to predict onorbit
performance of the flight configuration HGAS. Potential Deployment Interference
After the HGAS subsystem was integrated to the spacecraft, a potential
deployment interference issue{'source': 'AMS_2014.pdf', 'page': 68}\",3,\"Chunks\"],[\"16394cfa-bd43-11ee-801f-bae7cd9d315f\",3.0079112053,8.5311737061,\"Finally, we show that some of the lubricant that is displaced between the ball and race during run-in operation can be recovered during rest, and we measure the rate of recovery for one example. 1.0 Introduction Bearing life and performance is critically dependent on lubricant. Heat transfer is also dependent on lubricant in space, therefore the two are linked. This paper will show bearing thermal properties depend on lubricant and its quantity, then, show how the conductance measurements can be used to infer lubricant behavior. The requirements for operation of space mechanisms present bearings a very different thermal environment than mechanisms used in a terrestrial environment. In terrestrial applications, convection dominates the cooling mechanism. If air is not enough to cool it, the bearing is typically flooded with lubricant for additional cooling. Thus, bearing thermal conductance tends to be a second or third order effect in most terrestrial applications. However, in the vacuum of space, essentially no air is present and flooding with lubricant is not feasible. Furthermore, in most cases, the bearing must operate with parched lubricant quantities and perform for years under these conditions. In the absence of convection, bearing raceway temperatures are a productof bearing thermal conductance, heat generation, and the operational environmental temperature. In most *The Aerospace Corporation, El Segundo, CA **The Aerospace Corporation, Colorado Springs, CO{'source': 'AMS_2014.pdf', 'page': 129}\",\"Finally, we show that some of the lubricant that is displaced between the ball
and race during run-in operation can be recovered during rest, and we measure
the rate of recovery for one example. 1.0 Introduction Bearing life and
performance is critically dependent on lubricant. Heat transfer is also
dependent on lubricant in space, therefore the two are linked. This paper will
show bearing thermal properties depend on lubricant and its quantity, then, show
how the conductance measurements can be used to infer lubricant behavior. The
requirements for operation of space mechanisms present bearings a very different
thermal environment than mechanisms used in a terrestrial environment. In
terrestrial applications, convection dominates the cooling mechanism. If air is
not enough to cool it, the bearing is typically flooded with lubricant for
additional cooling. Thus, bearing thermal conductance tends to be a second or
third order effect in most terrestrial applications. However, in the vacuum of
space, essentially no air is present and flooding with lubricant is not
feasible. Furthermore, in most cases, the bearing must operate with parched
lubricant quantities and perform for years under these conditions. In the
absence of convection, bearing raceway temperatures are a productof bearing
thermal conductance, heat generation, and the operational environmental
temperature. In most *The Aerospace Corporation, El Segundo, CA **The Aerospace
Corporation, Colorado Springs, CO{'source': 'AMS_2014.pdf', 'page': 129}\",3,\"Chunks\"],[\"17aef0c6-bd43-11ee-801f-bae7cd9d315f\",6.9785842896,9.4924850464,\"014 HBR 179 Ratchet 0.89 40 4.02 189509 6535 C 015** HBR 179 Ratchet 0.78 40 4.56 222700 7679 F 016 HBR 179 Ratchet 0.81 41 4.42 208367 7185 A 017 HBR 179 Ratchet 0.90 39 3.85 188187 6489 C 018 JPL 179 Ratchet 1.15 37 3.26 149220 5146 A 019 JPL 179 Ratchet 1.01 39 3.44 167460 5774 D 020 JPL 179 Ratchet 0.88 39 3.78 198538 6846 D 021 JPL 179 Ratchet 1.04 37 3.48 173618 5987 A Lessons Learned A number of useful lessons were learned from the design and testing of the RANCOR drill. As with any design, there is still room for improvement, but in the end the drill was more than capable of performing coring tasks in medium to low strength rock targets. Also as requirements for Mars Sample Return (MSR)mature, there may be more mass and volume available to the drill design that can be utilized to increase the reliability and robustness. Lessons learned from the RANCOR drill include the following: 1. In this case, the cost and simplicity of an off-the-shelf sprag clutch versus the design and build of a custom ratchet and pawl system led to the decision to use the sprag clutch. Although there was nothing functionally wrong with the sprag in this design, it enabled a degree of freedom that should have been locked out during the release of the hammer on the RANCOR. Therefore, the sprag mechanism was replaced with a ratchet and pawl system. The result was a large improvement in core quality (from D through F grades to A and B grades).{'source': 'AMS_2014.pdf', 'page': 244}\",\"014 HBR 179 Ratchet 0.89 40 4.02 189509 6535 C 015** HBR 179 Ratchet 0.78 40
4.56 222700 7679 F 016 HBR 179 Ratchet 0.81 41 4.42 208367 7185 A 017 HBR 179
Ratchet 0.90 39 3.85 188187 6489 C 018 JPL 179 Ratchet 1.15 37 3.26 149220 5146
A 019 JPL 179 Ratchet 1.01 39 3.44 167460 5774 D 020 JPL 179 Ratchet 0.88 39
3.78 198538 6846 D 021 JPL 179 Ratchet 1.04 37 3.48 173618 5987 A Lessons
Learned A number of useful lessons were learned from the design and testing of
the RANCOR drill. As with any design, there is still room for improvement, but
in the end the drill was more than capable of performing coring tasks in medium
to low strength rock targets. Also as requirements for Mars Sample Return
(MSR)mature, there may be more mass and volume available to the drill design
that can be utilized to increase the reliability and robustness. Lessons learned
from the RANCOR drill include the following: 1. In this case, the cost and
simplicity of an off-the-shelf sprag clutch versus the design and build of a
custom ratchet and pawl system led to the decision to use the sprag clutch.
Although there was nothing functionally wrong with the sprag in this design, it
enabled a degree of freedom that should have been locked out during the release
of the hammer on the RANCOR. Therefore, the sprag mechanism was replaced with a
ratchet and pawl system. The result was a large improvement in core quality
(from D through F grades to A and B grades).{'source': 'AMS_2014.pdf', 'page':
244}\",3,\"Chunks\"],[\"18fa2f4a-bd43-11ee-801f-bae7cd9d315f\",3.5367951393,6.9706912041,\"plate. This configuration was chosen instead of the fully clamped one to simulate the actual balancing configuration in which the dynamometer\\u2019s own mode is in the vicinity of 30 Hz versus the 120 Hz+ in the fully clamped configuration. Three measurements were taken. In the first measurement, the data from the load cells is channeled only to an independent secondary data acquisition system (VXI system). In the second test, the data from the load cells is channeled to the BDMS data acquisition (processor to be used for balancing) and simultaneously to the VXI through a set of \\u201cT\\u201d connections. The third test has both data acquisition systems in place except that the data acquisition card of the BDMS was turned off. A digital filter of 10 Hz was applied to the data sets. An example of dynamometer noise floor measurement for the Y-axis is shown in Figure 5. The maximum noise of 0.00175 lb (0.00778 N )is measured and is found to be less than the 0.004 lb (0.018 N) needed to carry out accurate measurements to meet GMI spin balance requirements. Harmonic stinger test This test is intended to calibrate the measurements performed by the dynamometer as a system. The dynamometer is excited at a frequency of 10 Hz using an MTB 50-lb (220-N) stinger. A calibrated load cell is placed at the interface between the stinger and the dynamometer to measure the input force. The 310{'source': 'AMS_2014.pdf', 'page': 326}\",\"plate. This configuration was chosen instead of the fully clamped one to
simulate the actual balancing configuration in which the dynamometer\\u2019s own mode
is in the vicinity of 30 Hz versus the 120 Hz+ in the fully clamped
configuration. Three measurements were taken. In the first measurement, the data
from the load cells is channeled only to an independent secondary data
acquisition system (VXI system). In the second test, the data from the load
cells is channeled to the BDMS data acquisition (processor to be used for
balancing) and simultaneously to the VXI through a set of \\u201cT\\u201d connections. The
third test has both data acquisition systems in place except that the data
acquisition card of the BDMS was turned off. A digital filter of 10 Hz was
applied to the data sets. An example of dynamometer noise floor measurement for
the Y-axis is shown in Figure 5. The maximum noise of 0.00175 lb (0.00778 N )is
measured and is found to be less than the 0.004 lb (0.018 N) needed to carry
out accurate measurements to meet GMI spin balance requirements. Harmonic
stinger test This test is intended to calibrate the measurements performed by
the dynamometer as a system. The dynamometer is excited at a frequency of 10 Hz
using an MTB 50-lb (220-N) stinger. A calibrated load cell is placed at the
interface between the stinger and the dynamometer to measure the input force.
The 310{'source': 'AMS_2014.pdf', 'page': 326}\",3,\"Chunks\"],[\"199b50f0-bd43-11ee-801f-bae7cd9d315f\",6.6779203415,10.0152788162,\"(%)DUTY CYCLE (msec)VOLTAGE (Vdc)TORQUE PRIMARY (CW) Nm (lb-in)TORQUE PRIMARY (CCW) Nm (lb-in)TORQUE RED. (CW) Nm (lb-in)TORQUE RED. (CCW) Nm (lb-in) 1 4 40 23.13 21.5(190) 21.5(190) 21.5(190) 21.5(190) 1 5.1 51 23.13 21.5(190) 22.6(200) 21.5(190) 22.0(195) 1 8 80 23.13 22.6(200) 22.0(195) 21.5(190) 22.0(195) 1 8 80 27.39 22.6(200) 22.6(200) 22.0(195) 22.0(195) 10 40 40 23.13 21.5(190) 20.9(185) 21.5(190) 20.3(180) 10 51 51 23.13 20.3(180) 19.8(175) 20.9(185) 19.8(175) 10 80 80 23.13 21.5(190) 20.9(185) 21.5(190) 20.9(185) 10 80 80 27.39 21.5(190) 20.9(185) 22.0(195) 21.5(190) 358{'source': 'AMS_2014.pdf', 'page': 374}\",\"(%)DUTY CYCLE (msec)VOLTAGE (Vdc)TORQUE PRIMARY (CW) Nm (lb-in)TORQUE
PRIMARY (CCW) Nm (lb-in)TORQUE RED. (CW) Nm (lb-in)TORQUE RED. (CCW) Nm (lb-
in) 1 4 40 23.13 21.5(190) 21.5(190) 21.5(190) 21.5(190) 1 5.1 51 23.13
21.5(190) 22.6(200) 21.5(190) 22.0(195) 1 8 80 23.13 22.6(200) 22.0(195)
21.5(190) 22.0(195) 1 8 80 27.39 22.6(200) 22.6(200) 22.0(195) 22.0(195) 10 40
40 23.13 21.5(190) 20.9(185) 21.5(190) 20.3(180) 10 51 51 23.13 20.3(180)
19.8(175) 20.9(185) 19.8(175) 10 80 80 23.13 21.5(190) 20.9(185) 21.5(190)
20.9(185) 10 80 80 27.39 21.5(190) 20.9(185) 22.0(195) 21.5(190) 358{'source':
'AMS_2014.pdf', 'page': 374}\",3,\"Chunks\"],[\"1a56d1e0-bd43-11ee-801f-bae7cd9d315f\",3.2640552521,7.8682575226,\"actual magnitude of the pull-in torque at a desired pulse rate is more of an iterative process. A relatively simple method that is not as laborious of continually increasing the torque test by test is to run the actuator at the desired pulse rate and increase the torque until the unit pulls-out of synchronous operation. While the unit is \\u201cbuzzing\\u201d in this pulled out condition, decrease the brake torque until the actuator regains synchronous operation. Stop the unit and allow the actuator to return to room temperature, then test the pull-in torque at the torque value that returned the actuator to synchronous operation. A final minor adjustment may be necessary, but this value should be a negligible difference to the actual pull-in torque value. Now that the performance at room temperature has been characterized, it may be desired to simulate or test the performance at maximum temperature. It is actually simple to simulate high temperature performance at ambient room temperature by calculating the motor resistance and power input as described in Equation 7 and Appendix A. With the reduced power calculated, simply adjust the power input to the supply to apply the high temperature input power, and duplicate the dynamic tests described above. Adjusting the supply voltage cannot simulate testing an actuator at colder temperatures. While the electromagnetically generated torques are proportional in decreasing temperature, increased lube viscosity could dominate at colder temperatures and increase torque losses greater than the increased generated torque through reduced resistance. Testing inside a temperature chamber may be the only alternative, but if the cold temperature values are well within a lubricant\\u2019s rating, room temperature performance may be acceptable. Conclusion Linear interpretation to simulate stepper motor performance when introduced to load inertia, given motor{'source': 'AMS_2014.pdf', 'page': 403}\",\"actual magnitude of the pull-in torque at a desired pulse rate is more of an
iterative process. A relatively simple method that is not as laborious of
continually increasing the torque test by test is to run the actuator at the
desired pulse rate and increase the torque until the unit pulls-out of
synchronous operation. While the unit is \\u201cbuzzing\\u201d in this pulled out
condition, decrease the brake torque until the actuator regains synchronous
operation. Stop the unit and allow the actuator to return to room temperature,
then test the pull-in torque at the torque value that returned the actuator to
synchronous operation. A final minor adjustment may be necessary, but this value
should be a negligible difference to the actual pull-in torque value. Now that
the performance at room temperature has been characterized, it may be desired to
simulate or test the performance at maximum temperature. It is actually simple
to simulate high temperature performance at ambient room temperature by
calculating the motor resistance and power input as described in Equation 7 and
Appendix A. With the reduced power calculated, simply adjust the power input to
the supply to apply the high temperature input power, and duplicate the dynamic
tests described above. Adjusting the supply voltage cannot simulate testing an
actuator at colder temperatures. While the electromagnetically generated
torques are proportional in decreasing temperature, increased lube viscosity
could dominate at colder temperatures and increase torque losses greater than
the increased generated torque through reduced resistance. Testing inside a
temperature chamber may be the only alternative, but if the cold temperature
values are well within a lubricant\\u2019s rating, room temperature performance may
be acceptable. Conclusion Linear interpretation to simulate stepper motor
performance when introduced to load inertia, given motor{'source':
'AMS_2014.pdf', 'page': 403}\",3,\"Chunks\"],[\"1a56d2e4-bd43-11ee-801f-bae7cd9d315f\",7.0366444588,9.5628852844,\"Figure 9. Fishbone Diagram Failure Scenario Supporting Elements The following key findings related to the root cause investigation elements were utilized to devise a most probable failure scenario. 1.Test Video and Strain Gauge Data : Immediately after application of the qualification levels, the SM side assembly (aft cap, actuator housing, and forward cap) rotated clockwise (looking SM to umbilical side). Lagging this rotation, the secondary piston was observed to rotate counterclockwise. Inspection of data from strain gauges mounted on the secondary piston and visual indicators of mounted accelerometers indicated a rotation of approximately 90 degrees. Strain gauge data with indicators of tooling hole orientation relative to the Y-axis applied load can be found in Figure 10. Approximately 27 seconds after application of qualification levels (242 seconds) there was a noticeable decrease in noise and strut dynamic response. No noticeable damage was observed, so the test was continued to the full duration at 395 seconds. 2.Forward Lug Locking Patch Design : Load requirements for the locking patch were not defined prior to developmental testing. Designers did not anticipate any applied loosening torque to aid in the patch sizing in part due to the fact that the strut would be in compression during vibration testing.Additionally, it is not standard practice to perform supporting analyses of locking patch capability.Locking patches are not intended to serve as torque reaction features; rather, they should be used to reduce the rate of preload loss in a joint. The prevailing torque requirement was less than the minimum recommended running torques specified for fine thread series threads 38.1 mm (1.500 in) in diameter or less. The locking patch vendor indicated the patch size was small relative to the thread size and pitch to which they were applied. 3.Joint Characteristics : The threads utilized for testing had an as-designed preload limited to 25{'source': 'AMS_2014.pdf', 'page': 414}\",\"Figure 9. Fishbone Diagram Failure Scenario Supporting Elements The following
key findings related to the root cause investigation elements were utilized to
devise a most probable failure scenario. 1.Test Video and Strain Gauge Data :
Immediately after application of the qualification levels, the SM side assembly
(aft cap, actuator housing, and forward cap) rotated clockwise (looking SM to
umbilical side). Lagging this rotation, the secondary piston was observed to
rotate counterclockwise. Inspection of data from strain gauges mounted on the
secondary piston and visual indicators of mounted accelerometers indicated a
rotation of approximately 90 degrees. Strain gauge data with indicators of
tooling hole orientation relative to the Y-axis applied load can be found in
Figure 10. Approximately 27 seconds after application of qualification levels
(242 seconds) there was a noticeable decrease in noise and strut dynamic
response. No noticeable damage was observed, so the test was continued to the
full duration at 395 seconds. 2.Forward Lug Locking Patch Design : Load
requirements for the locking patch were not defined prior to developmental
testing. Designers did not anticipate any applied loosening torque to aid in the
patch sizing in part due to the fact that the strut would be in compression
during vibration testing.Additionally, it is not standard practice to perform
supporting analyses of locking patch capability.Locking patches are not intended
to serve as torque reaction features; rather, they should be used to reduce the
rate of preload loss in a joint. The prevailing torque requirement was less than
the minimum recommended running torques specified for fine thread series threads
38.1 mm (1.500 in) in diameter or less. The locking patch vendor indicated the
patch size was small relative to the thread size and pitch to which they were
applied. 3.Joint Characteristics : The threads utilized for testing had an as-
designed preload limited to 25{'source': 'AMS_2014.pdf', 'page': 414}\",3,\"Chunks\"],[\"1e4324b6-bd43-11ee-801f-bae7cd9d315f\",6.2449645996,5.9957976341,\"workenvelope constraints, Thisvolume wasroughly 7cm(2.75in)longitudinal by10cm(4in)lateralby 3.2cm(1.25in)tall.Evenwithinthoselimits,itwasstrongly desired tokeepactuator volume toa minimum, sincefutureapplications mayrequire multiple actuators ontheglove.Somecomponents ofthe system (e.g.powersupply, microprocessor, etc.)couldbelocated remotely inthebackpack (PLSS). Safetyisaprimeconsideration inspacesuit systems. Thisconcern ledtotherequirement ofno penetrations ofthepressure bladder forthissystem; allcomponents mustbeexternal. Thissystem must alsoavoidcreating ahazardous temperature insidetheglove.Amaximum temperature riseatthebase oftheactuator (backofglove)of40\\u00b0C(72\\u00b0F)overambient (poweroff)wassetasalimit.Thesystem mustbedesigned tofailsafe.Specifically, nocredible failuremodecancompromise theintegrity ofthe pressure suitorprevent theoperator fromperforming themanual tasksneeded toingress theairlock. Nostrictlimitonpowerrequirements wasinitiallyset.Aneventual flightsystem mustprovide sufficient powerforasix-hour EVAduration, andbeabletorejecttheheatdissipated internally. Thedesignintent atthisphasewastominimize powerconsumption giventherequired performance andotherconstraints. 9O{'source': 'AMS_2000.pdf', 'page': 104}\",\"workenvelope constraints, Thisvolume wasroughly 7cm(2.75in)longitudinal
by10cm(4in)lateralby 3.2cm(1.25in)tall.Evenwithinthoselimits,itwasstrongly
desired tokeepactuator volume toa minimum, sincefutureapplications mayrequire
multiple actuators ontheglove.Somecomponents ofthe system (e.g.powersupply,
microprocessor, etc.)couldbelocated remotely inthebackpack (PLSS).
Safetyisaprimeconsideration inspacesuit systems. Thisconcern ledtotherequirement
ofno penetrations ofthepressure bladder forthissystem; allcomponents
mustbeexternal. Thissystem must alsoavoidcreating ahazardous temperature
insidetheglove.Amaximum temperature riseatthebase oftheactuator
(backofglove)of40\\u00b0C(72\\u00b0F)overambient (poweroff)wassetasalimit.Thesystem
mustbedesigned tofailsafe.Specifically, nocredible failuremodecancompromise
theintegrity ofthe pressure suitorprevent theoperator fromperforming themanual
tasksneeded toingress theairlock. Nostrictlimitonpowerrequirements
wasinitiallyset.Aneventual flightsystem mustprovide sufficient powerforasix-hour
EVAduration, andbeabletorejecttheheatdissipated internally. Thedesignintent
atthisphasewastominimize powerconsumption giventherequired performance
andotherconstraints. 9O{'source': 'AMS_2000.pdf', 'page': 104}\",3,\"Chunks\"],[\"2037c79a-bd43-11ee-801f-bae7cd9d315f\",2.7576487064,8.6010456085,\"Figure 3 Materials: Asdiscussed earlier, allbearing components werefabricated fromnon-magnetic materials. Considerable effortsweremadetoobtainiron-free variants ofthemany\\\"common\\\" materials employed intheconstruction ofthegimbal. Lubrication: Nolubricants areemployed. Duetothesemi-cryogenic operational temperatures, no wetlubricants weresuitable. Theuseofjeweled bearings precluded theneedforanyadditional lubrication. Thecombination ofthematerials employed inthebearing resultsinacoefficient of frictionof0.15. Vibration: Thespringwithinthebearing isapotential singlepointfailuresothatattention mustbe concentrated onthisimportant aspectofthedesign. Areliability prediction wasperformed toverifya verylowfailurerateintheapplication ofthespring. Thespringuses0.2-mm diameter wirewithameancoildiameter of1.32mmdiameter. Thereare6 activecoilswithapitchof0.33mm.Thematerial isBeryllium-copper. Thespringrateforacompression springis: R=(modulus ofrigidity)(wire diameter_ 8(meanspringdiameter)3(Active coils) R=4.24Ibs.\\/in Thespringconcentration factoriswherer=coildiameter towirediameter 193{'source': 'AMS_2000.pdf', 'page': 207}\",\"Figure 3 Materials: Asdiscussed earlier, allbearing components werefabricated
fromnon-magnetic materials. Considerable effortsweremadetoobtainiron-free
variants ofthemany\\\"common\\\" materials employed intheconstruction ofthegimbal.
Lubrication: Nolubricants areemployed. Duetothesemi-cryogenic operational
temperatures, no wetlubricants weresuitable. Theuseofjeweled bearings precluded
theneedforanyadditional lubrication. Thecombination ofthematerials employed
inthebearing resultsinacoefficient of frictionof0.15. Vibration:
Thespringwithinthebearing isapotential singlepointfailuresothatattention mustbe
concentrated onthisimportant aspectofthedesign. Areliability prediction
wasperformed toverifya verylowfailurerateintheapplication ofthespring.
Thespringuses0.2-mm diameter wirewithameancoildiameter of1.32mmdiameter.
Thereare6 activecoilswithapitchof0.33mm.Thematerial isBeryllium-copper.
Thespringrateforacompression springis: R=(modulus ofrigidity)(wire diameter_
8(meanspringdiameter)3(Active coils) R=4.24Ibs.\\/in Thespringconcentration
factoriswherer=coildiameter towirediameter 193{'source': 'AMS_2000.pdf', 'page':
207}\",3,\"Chunks\"],[\"2037c952-bd43-11ee-801f-bae7cd9d315f\",7.6906294823,7.6343193054,\"_verArm Flexures TorqueTube StopArmon DriveHub Figure11aand11b.TheCoverDriveMechanism opensandcloses thecanister cover. ArmsAttached OI _toCanister Cover ..._._'I- (Torque TubeNotShown' Brackets Attached Canister Base (Support PlatesNotShown) GearmotorO Figure 12.0 b= 0 Bearing O Preload Spring_ r_ TheCoverDriveMechanism cross-sectionCable Spool 211{'source': 'AMS_2000.pdf', 'page': 225}\",\"_verArm Flexures TorqueTube StopArmon DriveHub
Figure11aand11b.TheCoverDriveMechanism opensandcloses thecanister cover.
ArmsAttached OI _toCanister Cover ..._._'I- (Torque TubeNotShown' Brackets
Attached Canister Base (Support PlatesNotShown) GearmotorO Figure 12.0 b= 0
Bearing O Preload Spring_ r_ TheCoverDriveMechanism cross-sectionCable Spool
211{'source': 'AMS_2000.pdf', 'page': 225}\",3,\"Chunks\"],[\"22d00684-bd43-11ee-801f-bae7cd9d315f\",4.8223829269,10.9381322861,\":':::'_ii':':i_:i_i_.:_:i_2! 1:2_2121;2_ii++222!2:2_!22;i! Figure7aFreonTFprocessed bearing scan ........................... .++......... ....;............. .........,..,..+.+,.,.. .................. ,........................................ +........... o.................... ....+,.:,., ......... ._,.,...... :......... ;....,+.++,,._+.,. \\/ ....... ,...... ,......................... ;........... .....,+ .............................................................. ,...................,.........,........................... _.2--\\\"'--.u-_%J Figure7c.HFE-7100 processed bearing scan........ ,,..:........ +........... \\u2022...:,..,: ............ ,,+. _k \\/ .)Jlill'_ 111 ___L\\\"!....i....i...._....i....i...._....i....:....i...._....:, Figure7b.VertrelXFprocessed bearingscan Alltracesat50rpm.Allscansrepresent slightlygreaterthanonebearinginner shaftrevolution. Figure7.Interimtorquetracesforpreloaded bearing pairsafterapproximately 2.8.10srevolutions !+i..........................i........._.........i........._.........::........._........_........_........--.--:.........i...........\\u2022..!....!...._....:....:....!....:....!....i....;....!....i* 1\\\"6.4oz'inl \\\"\\\"_...._....i....i........i....!....i\\\"'+!....i....i.....\\\" Figure8b.VertrelXFprocessed bearingscan{'source': 'AMS_2001.pdf', 'page': 41}\",\":':::'_ii':':i_:i_i_.:_:i_2! 1:2_2121;2_ii++222!2:2_!22;i!
Figure7aFreonTFprocessed bearing scan ........................... .++.........
....;............. .........,..,..+.+,.,.. ..................
,........................................ +........... o....................
....+,.:,., ......... ._,.,...... :......... ;....,+.++,,._+.,. \\/ .......
,...... ,......................... ;........... .....,+
..............................................................
,...................,.........,........................... _.2--\\\"'--.u-_%J
Figure7c.HFE-7100 processed bearing scan........ ,,..:........ +...........
\\u2022...:,..,: ............ ,,+. _k \\/ .)Jlill'_ 111
___L\\\"!....i....i...._....i....i...._....i....:....i...._....:,
Figure7b.VertrelXFprocessed bearingscan Alltracesat50rpm.Allscansrepresent
slightlygreaterthanonebearinginner shaftrevolution.
Figure7.Interimtorquetracesforpreloaded bearing pairsafterapproximately
2.8.10srevolutions !+i..........................i........._.........i........._.
........::........._........_........_........--.--
:.........i...........\\u2022..!....!...._....:....:....!....:....!....i....;....!....
i* 1\\\"6.4oz'inl \\\"\\\"_...._....i....i........i....!....i\\\"'+!....i....i.....\\\"
Figure8b.VertrelXFprocessed bearingscan{'source': 'AMS_2001.pdf', 'page': 41}\",3,\"Chunks\"],[\"245a24ee-bd43-11ee-801f-bae7cd9d315f\",6.9780030251,9.4912605286,\"between thebackstop ofthedoublehingeandthetapered wedgeofthelatchpin.Thetapered latchpin willnotallowanyplay.Itwilldothisbyspringing axiallyforward totakeupanygapthatwouldbeopened byplayinthehingeassembly. Thisgapisusuallycaused byclearances duetotolerances. TestsandResults Theobjectofthistestwastoseewhether thetapered latchpinassembly trulyhasremoved alloftheplay fromthemechanism. Table1showstheplayattheendofatypicalzeroplayhingelatchforside1and side2withthehingelatchassembly locked intheopenposition. Figure3shows thesetupofthe measuring equipment. Playwasmeasured intherotational direction. Thisisthedirection thatthehinge wouldnormally rotate.Theplayintheopened, rotational direction isaverylowvalue0.00254 -0.00381 mm(0.0001-0.00015 in)butisnotzero.Thiswascaused bythefactthatintestingitacertainamount of forcewasapplied tothehinge,about30g(1oz),sothatsomereading wouldappear onthedial indicator. Itwasnecessary todothistomakesuretheweightofthehingewasnotpreventing thehinge frommoving freely.Whentheforcewasapplied, itprobably pushed thelatchpinbackward inanaxial direction, causing somelooseness. Thereading wouldbeclosertozeroiflessforcewereused.Afterthe playinthehingewasmeasured, eachsideofthehingewastakenapartandtheaxlesandholeswere{'source': 'AMS_2001.pdf', 'page': 126}\",\"between thebackstop ofthedoublehingeandthetapered wedgeofthelatchpin.Thetapered
latchpin willnotallowanyplay.Itwilldothisbyspringing axiallyforward
totakeupanygapthatwouldbeopened byplayinthehingeassembly. Thisgapisusuallycaused
byclearances duetotolerances. TestsandResults Theobjectofthistestwastoseewhether
thetapered latchpinassembly trulyhasremoved alloftheplay fromthemechanism.
Table1showstheplayattheendofatypicalzeroplayhingelatchforside1and
side2withthehingelatchassembly locked intheopenposition. Figure3shows
thesetupofthe measuring equipment. Playwasmeasured intherotational direction.
Thisisthedirection thatthehinge wouldnormally rotate.Theplayintheopened,
rotational direction isaverylowvalue0.00254 -0.00381 mm(0.0001-0.00015
in)butisnotzero.Thiswascaused bythefactthatintestingitacertainamount of
forcewasapplied tothehinge,about30g(1oz),sothatsomereading wouldappear onthedial
indicator. Itwasnecessary todothistomakesuretheweightofthehingewasnotpreventing
thehinge frommoving freely.Whentheforcewasapplied, itprobably pushed
thelatchpinbackward inanaxial direction, causing somelooseness. Thereading
wouldbeclosertozeroiflessforcewereused.Afterthe playinthehingewasmeasured,
eachsideofthehingewastakenapartandtheaxlesandholeswere{'source': 'AMS_2001.pdf',
'page': 126}\",3,\"Chunks\"],[\"282473ea-bd43-11ee-801f-bae7cd9d315f\",4.0847411156,6.1787433624,\"70 pitch scale, located at a radius of 31. 06 mm from the mirror rotation axis. This sensor has a 1. 2-nm resolution, which is thus equivalent to 38. 6 nrad of mirror rotation. The encoder was originally meant for beam acquisition purposes, but can also be used as a feedback sensor (as an alternative to the external interferometer). \\n\\nFigure 3. Picture of the realized two -stepper IFPM. (Photo: TNO \\/ Gert Witvoet) \\n\\nThe piezosteppers are fed by four high- voltage space- qualified analog amplifiers, one for each of the four phases of the actuators. The voltage waveforms are generated by a dSpace data acquisition system with a 16- bit D\\/A converter; t he encoder (via a 24- bit digital encoder interface) and the interferometer (via a 16-bit A\\/D converter) are connected to the same dSpace system. This system offers a rapid prototyping environment in MATLAB \\/Simulink, which provides great flexibility in meas urement possibilities and controller design. \\n\\nSystem Behavior \\n\\nThe motion of the legs of the walking actuator is determined by the voltage distribution along the four phases as a function of time. Although the open- loop motion will never be perfectly linear, the exact shape of these voltage waveforms has a large influence on the velocity variatio ns during an actuator cycle [6]. For example, the horizontal and vertical motion of the first set of legs can be approximated by{'source': 'AMS_2016.pdf', 'page': 84}\",\"70 pitch scale, located at a radius of 31. 06 mm from the mirror rotation axis.
This sensor has a 1. 2-nm resolution, which is thus equivalent to 38. 6 nrad
of mirror rotation. The encoder was originally meant for beam acquisition
purposes, but can also be used as a feedback sensor (as an alternative to the
external interferometer). Figure 3. Picture of the realized two -stepper
IFPM. (Photo: TNO \\/ Gert Witvoet) The piezosteppers are fed by four high-
voltage space- qualified analog amplifiers, one for each of the four phases
of the actuators. The voltage waveforms are generated by a dSpace data
acquisition system with a 16- bit D\\/A converter; t he encoder (via a 24- bit
digital encoder interface) and the interferometer (via a 16-bit A\\/D converter)
are connected to the same dSpace system. This system offers a rapid prototyping
environment in MATLAB \\/Simulink, which provides great flexibility in meas
urement possibilities and controller design. System Behavior The motion
of the legs of the walking actuator is determined by the voltage distribution
along the four phases as a function of time. Although the open- loop motion
will never be perfectly linear, the exact shape of these voltage waveforms has
a large influence on the velocity variatio ns during an actuator cycle [6].
For example, the horizontal and vertical motion of the first set of legs can be
approximated by{'source': 'AMS_2016.pdf', 'page': 84}\",3,\"Chunks\"],[\"2bdc3824-bd43-11ee-801f-bae7cd9d315f\",5.1426267624,5.8477778435,\"199 A New Architecture for Absolute Optical Encoders \\n\\nTimothy Malcolm*, John Beasley * and Mike Jumper * \\n\\nAbstract BEI Precision Systems & Space has developed an encoder technology, nanoSeries, that can calibrate itself in-situ and correct most of the common causes of error in typical encoders. The new nanoSeries ARA design has detailed health and status readouts that can definitively indicate when a re- calibration is in order . The re- calibration process can be done on- orbit if desired. The units can accommodate either full revolutions or limited angle sweeps, and the principles are also applicable to linear encoders. \\n\\nIntroduction \\n\\nOptical encoders manufactured by BEI Precision Systems & Space (BEI) have been used in space since the earliest days of space flight. The combination of low we ight and high resolution relative to electromagnetic resolvers made them an obvious choice for many applications. Optical encoders have typically been of only a few types. \\n\\nThe primary type of optical encoder selected for commercial and industrial applications has been the incremental encoder. This type of encoder requires a return to an index or home pulse to index a counter, which then counts the number of \\u2018incremental\\u2019 pulses or bits that pass by. This is a very simple and robust concept but it has some disadvantages for space, primarily that if power should go off or the counter upset s,{'source': 'AMS_2016.pdf', 'page': 213}\",\"199 A New Architecture for Absolute Optical Encoders Timothy Malcolm*, John
Beasley * and Mike Jumper * Abstract BEI Precision Systems & Space has
developed an encoder technology, nanoSeries, that can calibrate itself in-situ
and correct most of the common causes of error in typical encoders. The new
nanoSeries ARA design has detailed health and status readouts that can
definitively indicate when a re- calibration is in order . The re- calibration
process can be done on- orbit if desired. The units can accommodate either full
revolutions or limited angle sweeps, and the principles are also applicable to
linear encoders. Introduction Optical encoders manufactured by BEI
Precision Systems & Space (BEI) have been used in space since the
earliest days of space flight. The combination of low we ight and high
resolution relative to electromagnetic resolvers made them an obvious
choice for many applications. Optical encoders have typically been of only a
few types. The primary type of optical encoder selected for commercial and
industrial applications has been the incremental encoder. This type of
encoder requires a return to an index or home pulse to index a counter,
which then counts the number of \\u2018incremental\\u2019 pulses or bits that pass by.
This is a very simple and robust concept but it has some disadvantages for
space, primarily that if power should go off or the counter upset
s,{'source': 'AMS_2016.pdf', 'page': 213}\",3,\"Chunks\"],[\"2c94b944-bd43-11ee-801f-bae7cd9d315f\",7.6605796814,7.5263586044,\"Slip Ring Elevation Rotary Joint Base bracket HRM NEA MLI Antenna Inertia Dummy Elevation Stage Azimuth Stage Azimuth Stepper Motor Waveguide Elevation Rotary Joint{'source': 'AMS_2016.pdf', 'page': 262}\",\"Slip Ring Elevation Rotary Joint Base bracket HRM NEA MLI Antenna
Inertia Dummy Elevation Stage Azimuth Stage Azimuth Stepper Motor
Waveguide Elevation Rotary Joint{'source': 'AMS_2016.pdf', 'page': 262}\",3,\"Chunks\"],[\"377b9ea4-bd43-11ee-801f-bae7cd9d315f\",6.9092364311,6.7066822052,\"tosurvive launch. Mounting thegimbaltotheopticalbenchalsoservedtosimplify thedesignbyreducing thenumber ofparts.Italsosimplified instrument assembly andintegration sincethedevelopment ofthe opticalbenchassembly wasdecoupled fromthedevelopment ofthegimbalassembly andbothcouldbe thenconnected ordisconnected whenrequired withminimal effort. NASA\\/C P--2002-211506 224{'source': 'AMS_2002.pdf', 'page': 240}\",\"tosurvive launch. Mounting thegimbaltotheopticalbenchalsoservedtosimplify
thedesignbyreducing thenumber ofparts.Italsosimplified instrument assembly
andintegration sincethedevelopment ofthe opticalbenchassembly wasdecoupled
fromthedevelopment ofthegimbalassembly andbothcouldbe thenconnected
ordisconnected whenrequired withminimal effort. NASA\\/C P--2002-211506
224{'source': 'AMS_2002.pdf', 'page': 240}\",3,\"Chunks\"],[\"3b365804-bd43-11ee-801f-bae7cd9d315f\",3.8486495018,10.7294206619,\"Mechanical Engineering Department, directed byProf.HariDharan. Theprepreg layerswerelaidbyhandonapolished aluminum mandrel, thenwrapped withafilmof PTFETeflon. Instead ofusinganautoclave orvacuum bagging, alengthofthick-walled neoprene heatshrinktubewasplacedaroundtheuncured tube.Theshrink temperature ofthetubingisthesameasthecuretemperature oftheepoxyinthe prepreg (175\\u00b0C). Theentireassembly wasbakedfortwohoursandcooled. Theshrink 79{'source': 'AMS_1998.pdf', 'page': 91}\",\"Mechanical Engineering Department, directed byProf.HariDharan. Theprepreg
layerswerelaidbyhandonapolished aluminum mandrel, thenwrapped withafilmof
PTFETeflon. Instead ofusinganautoclave orvacuum bagging, alengthofthick-walled
neoprene heatshrinktubewasplacedaroundtheuncured tube.Theshrink temperature
ofthetubingisthesameasthecuretemperature oftheepoxyinthe prepreg (175\\u00b0C).
Theentireassembly wasbakedfortwohoursandcooled. Theshrink 79{'source':
'AMS_1998.pdf', 'page': 91}\",3,\"Chunks\"],[\"3c5bc5f2-bd43-11ee-801f-bae7cd9d315f\",4.1136646271,10.7853841782,\"environment iscrucial. Standard graphite brushes thatoperate acceptably atsealevel provide verypoorperformance inlowpressure andvacuum conditions. Thisis because ofthelackofhumidity andatmosphere thatsupports thedevelopment ofan oxidelayeronthecommutator, thisfilmreduces boththemechanical andelectrical wearofthebrush. Another contributor toelectrical arcingistheinductive energystoredinthecoil.This formofelectrical arcingwascontrolled byincreasing thenumber ofcommutator barsas highaspossible. Themaximum number ofcommutator barsfeasible intheapplication waseleven. Thehighernumber ofcommutator barsthelessinductance andhence lessinductive energy. Thisreduces theelectrical stressonthebrush. Brusharcingwasthenfurtherreduced bytheaddition ofaceramic capacitor inparallel withthebrushassemblies. Theceramic capacitor actstosuppress arcingofthe brushes byreducing theeffective sourceimpedance athighfrequencies. 145{'source': 'AMS_1998.pdf', 'page': 157}\",\"environment iscrucial. Standard graphite brushes thatoperate acceptably
atsealevel provide verypoorperformance inlowpressure andvacuum conditions.
Thisis because ofthelackofhumidity andatmosphere thatsupports thedevelopment
ofan oxidelayeronthecommutator, thisfilmreduces boththemechanical andelectrical
wearofthebrush. Another contributor toelectrical arcingistheinductive
energystoredinthecoil.This formofelectrical arcingwascontrolled byincreasing
thenumber ofcommutator barsas highaspossible. Themaximum number ofcommutator
barsfeasible intheapplication waseleven. Thehighernumber ofcommutator
barsthelessinductance andhence lessinductive energy. Thisreduces theelectrical
stressonthebrush. Brusharcingwasthenfurtherreduced bytheaddition ofaceramic
capacitor inparallel withthebrushassemblies. Theceramic capacitor actstosuppress
arcingofthe brushes byreducing theeffective sourceimpedance athighfrequencies.
145{'source': 'AMS_1998.pdf', 'page': 157}\",3,\"Chunks\"],[\"3d062632-bd43-11ee-801f-bae7cd9d315f\",4.6170172691,10.8186187744,\"reaction wheelincorporating thesehybridbearings revealed nodamage afterthe bearings weresubjected toastresslevelof3780MPa. Introduction Thesuccessful design ofahigh-cycle spacecraft mechanism thatemploys bearings requires thatthebearing materials haveatleasttwoproperties: highrollingcontact fatigue (RCF)resistance tomeetoperational dynamic cycling requirements, and adequate staticloadcapacity tosurvive launch loads. Inrecentyears,testresults havebeenreported forhybridbearings consisting ofSi3N4ballsandsteelraceways in commercial machine toolspindles, inmilitary bearing applications, 1andintheSpace Shuttle mainengine liquidoxygen andfuelturbopumps. 2Suchhybridbearings appear toprovide goodfatigue performance andtoavoidmetal-to-metal contact, which, inturn,retards theonsetoflubricant degradation. Mostofthehybridbearing results reported todateuseexisting bearing steels(52100, 440C,M50,M50Nil), although Cronidur 30steelisplanned foruseintheSpace Shuttle fuelturbopump bearings. 3However, bearing materials areofinterest thatcanoperate underhigher stresswithlongerlife.Recently, apowder-metallurgy highspeedM62toolsteel, calledVIMREX20, orCRU20, hasemerged asagoodcandidate forimproved bearings duetoitshighhardness (HRC66-67) andwearresistance, finecarbide structure, andimproved RCFperformance. Earlyball-on-rod fatigue testshavebeen *TheAerospace Corporation, ElSegundo, CA MPBCorp.,Keene,NH +TimkenCo.,Canton, OH{'source': 'AMS_1998.pdf', 'page': 249}\",\"reaction wheelincorporating thesehybridbearings revealed nodamage afterthe
bearings weresubjected toastresslevelof3780MPa. Introduction Thesuccessful
design ofahigh-cycle spacecraft mechanism thatemploys bearings requires
thatthebearing materials haveatleasttwoproperties: highrollingcontact fatigue
(RCF)resistance tomeetoperational dynamic cycling requirements, and adequate
staticloadcapacity tosurvive launch loads. Inrecentyears,testresults
havebeenreported forhybridbearings consisting ofSi3N4ballsandsteelraceways in
commercial machine toolspindles, inmilitary bearing applications, 1andintheSpace
Shuttle mainengine liquidoxygen andfuelturbopumps. 2Suchhybridbearings appear
toprovide goodfatigue performance andtoavoidmetal-to-metal contact, which,
inturn,retards theonsetoflubricant degradation. Mostofthehybridbearing results
reported todateuseexisting bearing steels(52100, 440C,M50,M50Nil), although
Cronidur 30steelisplanned foruseintheSpace Shuttle fuelturbopump bearings.
3However, bearing materials areofinterest thatcanoperate underhigher
stresswithlongerlife.Recently, apowder-metallurgy highspeedM62toolsteel,
calledVIMREX20, orCRU20, hasemerged asagoodcandidate forimproved bearings
duetoitshighhardness (HRC66-67) andwearresistance, finecarbide structure,
andimproved RCFperformance. Earlyball-on-rod fatigue testshavebeen *TheAerospace
Corporation, ElSegundo, CA MPBCorp.,Keene,NH +TimkenCo.,Canton, OH{'source':
'AMS_1998.pdf', 'page': 249}\",3,\"Chunks\"],[\"40d597fc-bd43-11ee-801f-bae7cd9d315f\",6.6094326973,6.2874503136,\"I. im 1.1:'il,Q I I,_.___PANCAM &NAVCAM MASTSTOWED STRONGBACK t-1' \\/ \\/\\/--suspENSioN ROBOTICA_ _=_===\\/=__ _ ,.s_X__'_\\\"7 ASSEMBLY Figure 2.FIDORoverwithMastStowed andInstrument ArmDeployed 125{'source': 'AMS_1999.pdf', 'page': 139}\",\"I. im 1.1:'il,Q I I,_.___PANCAM &NAVCAM MASTSTOWED STRONGBACK t-1' \\/
\\/\\/--suspENSioN ROBOTICA_ _=_===\\/=__ _ ,.s_X__'_\\\"7 ASSEMBLY Figure
2.FIDORoverwithMastStowed andInstrument ArmDeployed 125{'source':
'AMS_1999.pdf', 'page': 139}\",3,\"Chunks\"],[\"44927f90-bd43-11ee-801f-bae7cd9d315f\",6.834312439,6.4797415733,\"TheAir-bearing Deployment Rig General Thedevelopment program, supported bytheDutchgovernment, hasbeenstructured intothefollowing phases: 1.Requirements definition ofnewdeployment rig 2.Breadboardtestprogram (singlebearing) 3.Development trolleytestprogram (onestandard trolley) 4.Replacement ofacomplete trolleyset(4trolleys) Forthedevelopment ofthenewdeployment rigthefollowing setof\\\"toplevel\\\" requirements havebeenderived: 1.Thefunctionality oftheoldrigshallatleastbecovered bythenewdesign, whichmeansthatcriticalinterface dimensions, suchasstowed interpanel spacing (50mm)shallbemaintained. 2.Theexisting rigstructure canbeusedwithonlyminormodifications. 3.Thetrolleydisturbance forceinthetransverse direction oftherigshallbeless than0.01Natatrolleysuspension loadof100N(0.1%). 4.Thetrolleydisturbance forceinthelongitudinal direction oftherigshallbe lessthan0.1Natatrolleysuspension loadof100N(1%). 5.Thetrolleys shallbelightweighttokeepdynamic disturbance forceslow. 6.Thedeployment rigimpactonthecleanroomenvironment shallbe minimized. 7.Themaintenance required bytherigshallbeminimized. 8.Theprocurement costsofatrolleyshallnotexceed thatoftheconventional trolley. Considering theserequirements, thenewdeployment rigtechnology hadtofitintothe existing riginfrastructure (railsystem andpanelspacing instowed wingsituation).{'source': 'AMS_1999.pdf', 'page': 421}\",\"TheAir-bearing Deployment Rig General Thedevelopment program, supported
bytheDutchgovernment, hasbeenstructured intothefollowing phases: 1.Requirements
definition ofnewdeployment rig 2.Breadboardtestprogram (singlebearing)
3.Development trolleytestprogram (onestandard trolley) 4.Replacement ofacomplete
trolleyset(4trolleys) Forthedevelopment ofthenewdeployment rigthefollowing
setof\\\"toplevel\\\" requirements havebeenderived: 1.Thefunctionality
oftheoldrigshallatleastbecovered bythenewdesign, whichmeansthatcriticalinterface
dimensions, suchasstowed interpanel spacing (50mm)shallbemaintained.
2.Theexisting rigstructure canbeusedwithonlyminormodifications.
3.Thetrolleydisturbance forceinthetransverse direction oftherigshallbeless
than0.01Natatrolleysuspension loadof100N(0.1%). 4.Thetrolleydisturbance
forceinthelongitudinal direction oftherigshallbe
lessthan0.1Natatrolleysuspension loadof100N(1%). 5.Thetrolleys
shallbelightweighttokeepdynamic disturbance forceslow. 6.Thedeployment
rigimpactonthecleanroomenvironment shallbe minimized. 7.Themaintenance required
bytherigshallbeminimized. 8.Theprocurement costsofatrolleyshallnotexceed
thatoftheconventional trolley. Considering theserequirements, thenewdeployment
rigtechnology hadtofitintothe existing riginfrastructure (railsystem
andpanelspacing instowed wingsituation).{'source': 'AMS_1999.pdf', 'page': 421}\",3,\"Chunks\"],[\"4688dcea-bd43-11ee-801f-bae7cd9d315f\",6.1103167534,10.4711399078,\"<45de_\\/min. Bending 3.96x104N\\u00b0m\\/deg (2.0x107in\\u00b0lbf\\/rad) Axial1.75x105N\\/cm(1.0x105Ibf\\/in) Combined bending moments abouttwoorthogonal axes2825N\\u00b0m(25,000in\\u00b0tbf), torsional load113N.m(1000in\\u00b0lbf),shearload3145N(707Ibf),axialload2224N (500Ibf) Combined bending moment abouttwoorthogonal axes,1130Nom(10,000in\\u00b0lbf) aboutoneaxis,10,170N.m(90,000in\\u00b0lbf)abouttheotheraxis(thebullgearis lockedfromrotatingusingalockrackwhileloadsareapplied), torsional load5085 N(45T000in\\u00b0lbf)_shearload3145N(707Ibf),axialload2224N(500Ibf) Random vibration_ composite Glevel8.8grms Operating Temperature -40to+60\\u00b0C(-40to+140\\u00b0F) 107kg(235Ib) Storage >10years,operating >10years 103{'source': 'AMS_1997.pdf', 'page': 119}\",\"<45de_\\/min. Bending 3.96x104N\\u00b0m\\/deg (2.0x107in\\u00b0lbf\\/rad)
Axial1.75x105N\\/cm(1.0x105Ibf\\/in) Combined bending moments abouttwoorthogonal
axes2825N\\u00b0m(25,000in\\u00b0tbf), torsional
load113N.m(1000in\\u00b0lbf),shearload3145N(707Ibf),axialload2224N (500Ibf) Combined
bending moment abouttwoorthogonal axes,1130Nom(10,000in\\u00b0lbf)
aboutoneaxis,10,170N.m(90,000in\\u00b0lbf)abouttheotheraxis(thebullgearis
lockedfromrotatingusingalockrackwhileloadsareapplied), torsional load5085
N(45T000in\\u00b0lbf)_shearload3145N(707Ibf),axialload2224N(500Ibf) Random vibration_
composite Glevel8.8grms Operating Temperature -40to+60\\u00b0C(-40to+140\\u00b0F)
107kg(235Ib) Storage >10years,operating >10years 103{'source': 'AMS_1997.pdf',
'page': 119}\",3,\"Chunks\"],[\"4688dd08-bd43-11ee-801f-bae7cd9d315f\",4.0638055801,10.6746759415,\"underacontrolled process, whichincluded immersion inheated cleantrichlor (43to 49\\u00b0C)ultrasonic cleaner for3to4minutes, thenair-blowing theteethandgroove. The cleaning process wasrepeated once. Thegreatest difficulty duringthedevelopment process wasthecleanliness ofthebull gearteeth.During machining operations, minute amounts ofoilbecame trapped atthe interface ofthesteelringsandthealuminum hubandseeped outduringthevacuum process, thereby contaminating thegearsurface andresulting inpoorgoldadhesion to thegearsurface. Theprocess development concentrated onthecleaning issue;for example, itwasfoundthatplacing thecleaned bullgearinthevacuum chamber and pumping downto10.4torr(totaltimeof1to1.5hr)pulledtheremaining smallamounts oftrapped oiltothesurface, whereitcouldeasilybewipedoffwithalcohol. This process wasrepeated onceortwice,thusresulting inaverycleangearsurface. Thetriodesputtering process involved placing thebullgearhorizontally onarotating tableinsideavacuum chamber withthealuminum hubcovered topandbottom (to prevent itfrombeingcoated). Thinsiliconwafercoupons, forverifying thecoating thickness, wereplaced infourplaces closetothegearteeth.Puregold(better than 99.50% purity)targets wereplaced oneachsideofthebullgear.Thevacuum chamber wasevacuated topressure ontheorderof10.5torrandback-filled withargongas.{'source': 'AMS_1997.pdf', 'page': 120}\",\"underacontrolled process, whichincluded immersion inheated cleantrichlor (43to
49\\u00b0C)ultrasonic cleaner for3to4minutes, thenair-blowing theteethandgroove. The
cleaning process wasrepeated once. Thegreatest difficulty duringthedevelopment
process wasthecleanliness ofthebull gearteeth.During machining operations,
minute amounts ofoilbecame trapped atthe interface ofthesteelringsandthealuminum
hubandseeped outduringthevacuum process, thereby contaminating thegearsurface
andresulting inpoorgoldadhesion to thegearsurface. Theprocess development
concentrated onthecleaning issue;for example, itwasfoundthatplacing thecleaned
bullgearinthevacuum chamber and pumping
downto10.4torr(totaltimeof1to1.5hr)pulledtheremaining smallamounts oftrapped
oiltothesurface, whereitcouldeasilybewipedoffwithalcohol. This process
wasrepeated onceortwice,thusresulting inaverycleangearsurface.
Thetriodesputtering process involved placing thebullgearhorizontally onarotating
tableinsideavacuum chamber withthealuminum hubcovered topandbottom (to prevent
itfrombeingcoated). Thinsiliconwafercoupons, forverifying thecoating thickness,
wereplaced infourplaces closetothegearteeth.Puregold(better than 99.50%
purity)targets wereplaced oneachsideofthebullgear.Thevacuum chamber wasevacuated
topressure ontheorderof10.5torrandback-filled withargongas.{'source':
'AMS_1997.pdf', 'page': 120}\",3,\"Chunks\"],[\"4a946534-bd43-11ee-801f-bae7cd9d315f\",3.4018511772,7.3716697693,\"0 0 0 10 61 4 49 1 20 769 615 40 962 769 60 1090, 875 80 1198 958 Additionally, it should be noted that the bearings were not run-in prior to testing. Experimental Errors Experimental errors arise from the errors in the measurements of thermal gradients across the bearing and along the HFM. Experimental errors are governed by the accuracy of the temperature sensors (L0.5 K at room temperature and 20.2 K at 20K). Further errors result from heat loss and in the dimensions of the HFM. A summary of experimental errors is now presented. Room Temp: HFM calibration errors are of the order of +25%, and the dimensional tolerances give the error in L = L2%, and the error in A = +1%. At 48 mW heater power, typical temperature differentials across the bearing were 2 to 4K. As the sensors are only accurate to k0.5 K, experimental errors on temperature measurements are, respectively, L50% and +25%, Combining this error with HFM calibration and dimensional errors gives a maximum experimental error of approximately +80 Yo. Increasing the heater power to 180 mW resulted in larger temperature gradients, and hence the measured temperature difference errors were reduced by a factor of 4 to 5, Le., errors are of the order of +loo\\/& The resulting experimental errors, including HFM calibration and dimensional errors, were of the order of +40% to f50%. Cryoaenic Temperatures: The improved sensitivities of the temperature sensors, at cryogenic temperatures, resulted in HFM calibration errors of +lo%. Combining these{'source': 'AMS_1996.pdf', 'page': 50}\",\"0 0 0 10 61 4 49 1 20 769 615 40 962 769 60 1090, 875 80 1198 958
Additionally, it should be noted that the bearings were not run-in prior to
testing. Experimental Errors Experimental errors arise from the errors in the
measurements of thermal gradients across the bearing and along the HFM.
Experimental errors are governed by the accuracy of the temperature sensors
(L0.5 K at room temperature and 20.2 K at 20K). Further errors result from heat
loss and in the dimensions of the HFM. A summary of experimental errors is now
presented. Room Temp: HFM calibration errors are of the order of +25%, and the
dimensional tolerances give the error in L = L2%, and the error in A = +1%. At
48 mW heater power, typical temperature differentials across the bearing were 2
to 4K. As the sensors are only accurate to k0.5 K, experimental errors on
temperature measurements are, respectively, L50% and +25%, Combining this error
with HFM calibration and dimensional errors gives a maximum experimental error
of approximately +80 Yo. Increasing the heater power to 180 mW resulted in
larger temperature gradients, and hence the measured temperature difference
errors were reduced by a factor of 4 to 5, Le., errors are of the order of
+loo\\/& The resulting experimental errors, including HFM calibration and
dimensional errors, were of the order of +40% to f50%. Cryoaenic Temperatures:
The improved sensitivities of the temperature sensors, at cryogenic
temperatures, resulted in HFM calibration errors of +lo%. Combining
these{'source': 'AMS_1996.pdf', 'page': 50}\",3,\"Chunks\"],[\"4ed60d32-bd43-11ee-801f-bae7cd9d315f\",4.8728985786,11.0012378693,\"QSS pe~ormed preliminary analyses on the MCF to approximate the local stresses adjacent to the underside lip area and to determine the material properties required for the development test articles. Two development test articles were fabricated, one from CRES Custom 455 and one from OSS performed early development testing using an lnstron machine to verify the results of the preliminary analyses. The development test units were subjected to the on-orbit loading forces of 184 N-m (250 ft-lbf) in torsion, 227 kg (550 Ibf) in axial compression and tension, and a combined loading of 227 kg (550 Ibf) in shear and 184 N-m (250 ft-lbf) in bending. Each test unit was instrumented with four rosette strain gauges positioned 90' apart on the inner surface of the through hole to allow for future correlation of stresses with the detailed FEA model. In order to simulate the loads applied by the micro conical tool tip, OSS fabricated a test jig that housed six beryllium copper collets, using preliminary material selected for the RMCT and EMCT collets. The MCF test units withstood all nominal loading conditions without any evidence of yield or failure. During an unscheduled test when the MCF test units were subjected to a maximum of 6342 N-m (8600 ft-lbf), the collets of the tool test jig yielded. Although no yielding was observed at the MCF lip, there was substantial compressive plastic deformation from the tool tip on the upper surface of the torque reaction shoulders. Fracture Analvses The MCFs do not satisfy NASA ISS requirements for a non-fracture critical component.{'source': 'AMS_1996.pdf', 'page': 384}\",\"QSS pe~ormed preliminary analyses on the MCF to approximate the local stresses
adjacent to the underside lip area and to determine the material properties
required for the development test articles. Two development test articles were
fabricated, one from CRES Custom 455 and one from OSS performed early
development testing using an lnstron machine to verify the results of the
preliminary analyses. The development test units were subjected to the on-orbit
loading forces of 184 N-m (250 ft-lbf) in torsion, 227 kg (550 Ibf) in axial
compression and tension, and a combined loading of 227 kg (550 Ibf) in shear and
184 N-m (250 ft-lbf) in bending. Each test unit was instrumented with four
rosette strain gauges positioned 90' apart on the inner surface of the through
hole to allow for future correlation of stresses with the detailed FEA model.
In order to simulate the loads applied by the micro conical tool tip, OSS
fabricated a test jig that housed six beryllium copper collets, using
preliminary material selected for the RMCT and EMCT collets. The MCF test units
withstood all nominal loading conditions without any evidence of yield or
failure. During an unscheduled test when the MCF test units were subjected to a
maximum of 6342 N-m (8600 ft-lbf), the collets of the tool test jig yielded.
Although no yielding was observed at the MCF lip, there was substantial
compressive plastic deformation from the tool tip on the upper surface of the
torque reaction shoulders. Fracture Analvses The MCFs do not satisfy NASA ISS
requirements for a non-fracture critical component.{'source': 'AMS_1996.pdf',
'page': 384}\",3,\"Chunks\"],[\"5168f76c-bd43-11ee-801f-bae7cd9d315f\",2.7984404564,9.5620718002,\"indicate that the elevated temperature of 100\\u00b0C was sufficient to establish a beneficial VAL between the steel and this coating. An effective VAL is one that inhibits high amounts of wear of the coating and the counterface over the temperature range and relative motion experienced by a specific application. Although Ti-MoS 2 has been previously shown to perform exceptionally well in rolling contact [4,9,12], based upon the results of these measurements, it can be concluded that the Ti-MoS 2 coating would meet the VAL requirements better than the tested MoS 2 and Sb 2O3\\/Au-MoS 2 coatings when in contact with reciprocating sliding steel counterfaces over a temperature range of 30\\u00b0C to 100\\u00b0C. It is important to point out that although the experiments were performed in laboratory air, the environment had a very low humidity (17% RH) during the testing. Although it is expected that the wear rates of all three coatings will increase with increasing relative humidity, undoped MoS 2 tends to experience the greatest increase [3]. NASA\\/CP\\u20142018-219887 147{'source': 'AMS_2018.pdf', 'page': 165}\",\"indicate that the elevated temperature of 100\\u00b0C was sufficient to establish a
beneficial VAL between the steel and this coating. An effective VAL is one
that inhibits high amounts of wear of the coating and the counterface over the
temperature range and relative motion experienced by a specific application.
Although Ti-MoS 2 has been previously shown to perform exceptionally well in
rolling contact [4,9,12], based upon the results of these measurements, it can
be concluded that the Ti-MoS 2 coating would meet the VAL requirements better
than the tested MoS 2 and Sb 2O3\\/Au-MoS 2 coatings when in contact with
reciprocating sliding steel counterfaces over a temperature range of 30\\u00b0C to
100\\u00b0C. It is important to point out that although the experiments were
performed in laboratory air, the environment had a very low humidity (17% RH)
during the testing. Although it is expected that the wear rates of all three
coatings will increase with increasing relative humidity, undoped MoS 2 tends to
experience the greatest increase [3]. NASA\\/CP\\u20142018-219887 147{'source':
'AMS_2018.pdf', 'page': 165}\",3,\"Chunks\"],[\"5aaadf8e-bd43-11ee-801f-bae7cd9d315f\",2.7705030441,9.7649517059,\"Chip qualification campaign In parallel of the previous TRP activity, a complete qualification of the chip itself, in accordance with space standards for the qualification of monolithic chip, is undertaken. Tests foreseen in this chip qualification activity can be divided in three steps: \\/g131 The production control tests which occur at the manufacturer level \\/g131 The screening tests \\/g131 The qualification tests \\n\\nProduction control tests\\n\\nThe wafer lot acceptance tests occur at the manufacturer level: The manufacturing of the wafers is monitor and PVM data are recorded during the whole process. The final lot is inspected through scanning electron microscope. Then, in-process controls occur at the packaging level: After a pre-encapsulation visual inspection, bond strength and die shear tests are implemented. After the chip encapsulation, a dimension check of each packaged chip is performed. Screening tests These tests are performed on all the components. Screening tests consist mainly to reject faulty chips though hard electrical and temperature testing. During those tests, the drift parameters of the chip are monitored and compare to failure criteria. The following tests are foreseen: \\/g131 The serialized chips are subjected to a high temperature stabilisation bake (24h at 150\\u00b0C) to determine the effect of storage at elevated temperatures without electrical stress applied. Drift parameters are monitored and control during the entire test. \\/g131 The chips are then be subjected to several burn-in tests at 125\\u00b0C (reverse bias and power burnin) in order to eliminating marginal devices, those with inherent defects which cause time and stress dependent failures. Drift parameters are monitored and control during the entire test. \\/g131 A measure of the drift parameters at ambient temperature is then foreseen and allow for the lot qualification.{'source': 'AMS_2008.pdf', 'page': 197}\",\"Chip qualification campaign In parallel of the previous TRP activity, a
complete qualification of the chip itself, in accordance with space standards
for the qualification of monolithic chip, is undertaken. Tests foreseen in this
chip qualification activity can be divided in three steps: \\/g131 The production
control tests which occur at the manufacturer level \\/g131 The screening tests
\\/g131 The qualification tests Production control tests The wafer lot
acceptance tests occur at the manufacturer level: The manufacturing of the
wafers is monitor and PVM data are recorded during the whole process. The final
lot is inspected through scanning electron microscope. Then, in-process controls
occur at the packaging level: After a pre-encapsulation visual inspection, bond
strength and die shear tests are implemented. After the chip encapsulation, a
dimension check of each packaged chip is performed. Screening tests These tests
are performed on all the components. Screening tests consist mainly to reject
faulty chips though hard electrical and temperature testing. During those tests,
the drift parameters of the chip are monitored and compare to failure criteria.
The following tests are foreseen: \\/g131 The serialized chips are subjected to a
high temperature stabilisation bake (24h at 150\\u00b0C) to determine the effect of
storage at elevated temperatures without electrical stress applied. Drift
parameters are monitored and control during the entire test. \\/g131 The chips
are then be subjected to several burn-in tests at 125\\u00b0C (reverse bias and power
burnin) in order to eliminating marginal devices, those with inherent defects
which cause time and stress dependent failures. Drift parameters are monitored
and control during the entire test. \\/g131 A measure of the drift parameters at
ambient temperature is then foreseen and allow for the lot
qualification.{'source': 'AMS_2008.pdf', 'page': 197}\",3,\"Chunks\"],[\"625338ee-bd43-11ee-801f-bae7cd9d315f\",3.2289829254,7.7788219452,\"curvatures can lead to early failure, a claim that to the best of our understanding has never been documented. In addition, the testing performed in this investigation and its associated findings are of value to designers of bearings for scanners, gimbals, and other rotary spacecraft actuators. \\n\\n* NASA Langley Research Center, Hampton, VA ** Fisher Aerospace, Sunnyvale, CA + Lockheed Martin Space (retired) , Sunnyvale, CA ++ The Aerospace Corporation, El Segundo, CA{'source': 'AMS_2020.pdf', 'page': 287}\",\"curvatures can lead to early failure, a claim that to the best of our
understanding has never been documented. In addition, the testing performed in
this investigation and its associated findings are of value to designers of
bearings for scanners, gimbals, and other rotary spacecraft actuators. * NASA
Langley Research Center, Hampton, VA ** Fisher Aerospace, Sunnyvale, CA +
Lockheed Martin Space (retired) , Sunnyvale, CA ++ The Aerospace Corporation,
El Segundo, CA{'source': 'AMS_2020.pdf', 'page': 287}\",3,\"Chunks\"],[\"62533a2e-bd43-11ee-801f-bae7cd9d315f\",2.8198668957,9.2502098083,\"290 Figure 4. Plot of film oil film thickness vs time during blow -off using the TFF \\n\\nFigure 5. Plot of the data shown in Figure 4, using reciprocal of film thickness on the y -axis to show the inverse proportionality with time \\n\\nThese changes in viscosity and flow rate are important, because the process of resupply to the tribological contacts may be slowed as lubricant consumption proceeds and the scarcit y of free oil leads to reduced oil film thicknesses. \\n\\nTribometry and Viscosity of Worn Lubricant Films \\n\\nAnother significant reduction in oil mobility during operational use may be caused by changes in oil composition. As the lubricant is worn in a tribological contact due to mechanical stresses and chemical reactions, some molecules are broken into smaller components while others are polym erized into larger{'source': 'AMS_2020.pdf', 'page': 300}\",\"290 Figure 4. Plot of film oil film thickness vs time during blow -off using
the TFF Figure 5. Plot of the data shown in Figure 4, using reciprocal of
film thickness on the y -axis to show the inverse proportionality with time
These changes in viscosity and flow rate are important, because the process of
resupply to the tribological contacts may be slowed as lubricant consumption
proceeds and the scarcit y of free oil leads to reduced oil film thicknesses.
Tribometry and Viscosity of Worn Lubricant Films Another significant
reduction in oil mobility during operational use may be caused by changes in oil
composition. As the lubricant is worn in a tribological contact due to
mechanical stresses and chemical reactions, some molecules are broken into
smaller components while others are polym erized into larger{'source':
'AMS_2020.pdf', 'page': 300}\",3,\"Chunks\"],[\"661b4f52-bd43-11ee-801f-bae7cd9d315f\",3.6215083599,10.6665582657,\"resulted in incomplete removal of the flux from the solder , and this was also confirmed by radiography . This problem was further exacerbated by the higher revised qualification temperature. The manufacturer proposed waveguides with electroformed flange joints, which were considered superior to the soldered joint. After a thorough review of all options it was decided to change the waveguide configuration to the electroformed flange joint as proposed by the ma nufacturer . The program also decided to switch the exterior finish to black paint inst ead of nickel plating to lower the temperature of the middle section during operation. \\n\\nFigure 2. WR -34 Flexible Waveguide \\n\\nThe flight waveguide was made up of electroformed Ni-Co flexible section with the copper flanges attached by the electrofor ming process. T he interior surfaces were silver plated and the exterior surfaces were painted with BR -127 black paint . Following a successful batch qualification and acc eptance program, these waveguides were installed to flight HGA assembly. The development and flight waveguides are shown in Figure 2. \\n\\nWaveguide Analyses and Test s \\n\\nThe FWG was subjected t o a comprehensive evaluation program that included testing in three phases, development test, flight batch qualification test and acceptance tests. These test s consisted of environmental tests and mechanical functional tests. The condition of the FWG was monitored by RF{'source': 'AMS_2020.pdf', 'page': 541}\",\"resulted in incomplete removal of the flux from the solder , and this was also
confirmed by radiography . This problem was further exacerbated by the higher
revised qualification temperature. The manufacturer proposed waveguides with
electroformed flange joints, which were considered superior to the soldered
joint. After a thorough review of all options it was decided to change the
waveguide configuration to the electroformed flange joint as proposed by the
ma nufacturer . The program also decided to switch the exterior finish to black
paint inst ead of nickel plating to lower the temperature of the middle section
during operation. Figure 2. WR -34 Flexible Waveguide The flight waveguide
was made up of electroformed Ni-Co flexible section with the copper flanges
attached by the electrofor ming process. T he interior surfaces were silver
plated and the exterior surfaces were painted with BR -127 black paint .
Following a successful batch qualification and acc eptance program, these
waveguides were installed to flight HGA assembly. The development and flight
waveguides are shown in Figure 2. Waveguide Analyses and Test s The FWG
was subjected t o a comprehensive evaluation program that included testing in
three phases, development test, flight batch qualification test and acceptance
tests. These test s consisted of environmental tests and mechanical functional
tests. The condition of the FWG was monitored by RF{'source': 'AMS_2020.pdf',
'page': 541}\",3,\"Chunks\"],[\"66d6ac5c-bd43-11ee-801f-bae7cd9d315f\",6.1382699013,10.6633863449,\"15 Lessons Learned Several lessons were learned during the development of a deployable cover capable of holding a hermetic seal from prototype to flight. Hermetic Sealing - H-seals and conflat seals are ideal for hermetically sealing interfaces, especially when metal on metal interfaces are required. - It is critical that the sealing surface of H-seal and knife-edge interface are pristine surfaces free of burrs, nicks, and markings. - Knife-edge interfaces need to be able to fully engage with the sealing surface. - When loading H-seals onto a knife-edge, the seal needs to come down consistently perpendicular to the surface plane. The seal cannot be rocked or unevenly engaged onto knife-edge during loading. o For deployable mechanisms, this means compliance for the seal to come down perpendicular, and not on an extended radius from a hinge line (if applicable). Clampring - When tensioning a clampring with an under-center link, the majority of loading occurs during the initial movement of the linkage. There is limited load adjustability once the under-center linkage is near its end of travel towards the over-center condition. - Variability in ring ODs, even by .025 mm (.001 in), greatly affects the final tension in the clampring. Those features need to be very tightly controlled to get repeatable results between mechanisms. Helium Leak Testing - It is critical to minimize all potential interfaces when testing minimal levels of Helium in the system. - Excess background helium needs to be cleared from the immediate area of a leak detector - The leak detector needs to be in pristine condition to measure at noise floor. Any undesirable{'source': 'AMS_2022.pdf', 'page': 29}\",\"15 Lessons Learned Several lessons were learned during the development of a
deployable cover capable of holding a hermetic seal from prototype to flight.
Hermetic Sealing - H-seals and conflat seals are ideal for hermetically sealing
interfaces, especially when metal on metal interfaces are required. - It is
critical that the sealing surface of H-seal and knife-edge interface are
pristine surfaces free of burrs, nicks, and markings. - Knife-edge interfaces
need to be able to fully engage with the sealing surface. - When loading
H-seals onto a knife-edge, the seal needs to come down consistently
perpendicular to the surface plane. The seal cannot be rocked or unevenly
engaged onto knife-edge during loading. o For deployable mechanisms, this means
compliance for the seal to come down perpendicular, and not on an extended
radius from a hinge line (if applicable). Clampring - When tensioning a
clampring with an under-center link, the majority of loading occurs during the
initial movement of the linkage. There is limited load adjustability once the
under-center linkage is near its end of travel towards the over-center
condition. - Variability in ring ODs, even by .025 mm (.001 in), greatly
affects the final tension in the clampring. Those features need to be very
tightly controlled to get repeatable results between mechanisms. Helium Leak
Testing - It is critical to minimize all potential interfaces when testing
minimal levels of Helium in the system. - Excess background helium needs to be
cleared from the immediate area of a leak detector - The leak detector needs to
be in pristine condition to measure at noise floor. Any undesirable{'source':
'AMS_2022.pdf', 'page': 29}\",3,\"Chunks\"],[\"6772cbf0-bd43-11ee-801f-bae7cd9d315f\",2.8167743683,9.3256397247,\"heating and from austentie to a mix of martensite and R-phase upon cooling, the test could not be considered repeatable, and the predicate of the model is violated. While the model strongly correlates with physical principles and expected actuation behavior, training SMA to transition from only detwinned martensite to austenite at a specific temperature is non-trivial. Methods exist to remove the spurious phases, though more testing is warranted on purchased specimens with consistent material properties. An increase in the initial furnace temperature leads to a shorter and less pronounced R-phase plateau [12]. In Halvorson et al [10], spike phases were postulated as effects of quenching in liquid nitrogen instead of an ice bath; this has been determined to be incorrect. Multiple DSC test iterations with an ice water quench resulted in spike phases occurring where R-phase is expected near the Austenite finish temperature. The evolution to R-phase to glass phase is poorly documented in literature. It is asserted that the spike phases are glass transition phases; glass phases can occur ranging from 12%-82% nickel by mass [13]. Predictive Actuation Model The thermal, constitutive, and kinematic behavior of the SMA actuation process was modeled with a MATLAB simulation code divided into three elements: a heat transfer model, a thermo-mechanical model, and a kinematic model. SMA transient thermal response to PH operation in the bending region was determined using a quasi-3D, finite-difference heat transfer model with simulated conduction, convection, and radiation heat transfer effects corresponding to lab and PH input conditions. The thermo-mechanical{'source': 'AMS_2022.pdf', 'page': 78}\",\"heating and from austentie to a mix of martensite and R-phase upon cooling, the
test could not be considered repeatable, and the predicate of the model is
violated. While the model strongly correlates with physical principles and
expected actuation behavior, training SMA to transition from only detwinned
martensite to austenite at a specific temperature is non-trivial. Methods
exist to remove the spurious phases, though more testing is warranted on
purchased specimens with consistent material properties. An increase in the
initial furnace temperature leads to a shorter and less pronounced R-phase
plateau [12]. In Halvorson et al [10], spike phases were postulated as effects
of quenching in liquid nitrogen instead of an ice bath; this has been
determined to be incorrect. Multiple DSC test iterations with an ice water
quench resulted in spike phases occurring where R-phase is expected near the
Austenite finish temperature. The evolution to R-phase to glass phase is poorly
documented in literature. It is asserted that the spike phases are glass
transition phases; glass phases can occur ranging from 12%-82% nickel by mass
[13]. Predictive Actuation Model The thermal, constitutive, and kinematic
behavior of the SMA actuation process was modeled with a MATLAB simulation code
divided into three elements: a heat transfer model, a thermo-mechanical model,
and a kinematic model. SMA transient thermal response to PH operation in the
bending region was determined using a quasi-3D, finite-difference heat transfer
model with simulated conduction, convection, and radiation heat transfer
effects corresponding to lab and PH input conditions. The thermo-
mechanical{'source': 'AMS_2022.pdf', 'page': 78}\",3,\"Chunks\"],[\"f723a572-bd42-11ee-801f-bae7cd9d315f\",5.6985211372,10.8252334595,\"Parallel Corrugated Diaphragms m I s 7 1 I k- Bearings Flex link L Interface r \\/- Titanium Housing Figure 4. CRISM Diaphragm Bearing Assembly Anti-Sunward Radiator The CRlSM duplex bearing pairs were separated by titanium spacers so that the preload offset would remain constant over temperature. However, the difference between the 440C inner and outer rings and the titanium shaft and housing resulted in a reduction of clearance as temperature decreased (Figure 6). A reduction of clearance results in a decrease of the contact angle. However, the bearings are only going to experience substantial axial loads during the launch. The bearings were tested to -196\\u00b0C and continued to rotate freely. The few disadvantages of preloading are more than offset by the following advantages: Reduces axial and radial runout of the rotating shaft. Required for the encoder disk to read head alignment Reduces the shaft deflection under load and improves its assembled stiffness Removes free play in the bearing set, keeping the bearing set loaded in-order to avoid skidding of the balls Minimizes the peak stresses that occur during the maximum loading events by ensuring the load on the bearings is shared by more balls in each bearing 0 Decreases bearing noise In addition to the axial preload, the CRlSM bearings employed a light interference fit, 12.7 pm (0.0005 in) in the bearingkhaft fit and 15.2 pm (0.0006 in) in the bearing\\/housing fit. 14{'source': 'AMS_2006.pdf', 'page': 28}\",\"Parallel Corrugated Diaphragms m I s 7 1 I k- Bearings Flex link L
Interface r \\/- Titanium Housing Figure 4. CRISM Diaphragm Bearing Assembly
Anti-Sunward Radiator The CRlSM duplex bearing pairs were separated by
titanium spacers so that the preload offset would remain constant over
temperature. However, the difference between the 440C inner and outer rings and
the titanium shaft and housing resulted in a reduction of clearance as
temperature decreased (Figure 6). A reduction of clearance results in a
decrease of the contact angle. However, the bearings are only going to
experience substantial axial loads during the launch. The bearings were tested
to -196\\u00b0C and continued to rotate freely. The few disadvantages of preloading
are more than offset by the following advantages: Reduces axial and radial
runout of the rotating shaft. Required for the encoder disk to read head
alignment Reduces the shaft deflection under load and improves its assembled
stiffness Removes free play in the bearing set, keeping the bearing set loaded
in-order to avoid skidding of the balls Minimizes the peak stresses that occur
during the maximum loading events by ensuring the load on the bearings is
shared by more balls in each bearing 0 Decreases bearing noise In addition to
the axial preload, the CRlSM bearings employed a light interference fit, 12.7 pm
(0.0005 in) in the bearingkhaft fit and 15.2 pm (0.0006 in) in the
bearing\\/housing fit. 14{'source': 'AMS_2006.pdf', 'page': 28}\",3,\"Chunks\"],[\"f976480c-bd42-11ee-801f-bae7cd9d315f\",7.2174172401,7.0499854088,\"Nose Landina Gear Udock Mechanism The Space Shuttle Orbiter\\u2019s nose landing gear, nose landing gear door, and nose landing gear uplock mechanism, shown in Figure 1, are interconnected, and must be rigged and operated together. Following replacement of the door environmental seal, rigging was performed to achieve proper seal compression. During nose landing gear cycling, the gear uplock indication did not illuminate because the mechanism did not reach the full uplock condition. Binding in the rotational fitting between the uplock fitting and the bellcrank prevented the uplock mechanism from going to the full over-center position for gear uplock. Measurements of the width of the bellcrank and the internal width of the fitting showed an interference fit between the two assemblies. Rework on the bushings per specification requirements removed the interference condition, allowing the bellcrank to move freely. Lesson Learned: Proper tolerancing and inspection are critical to preventing interferences in mechanical systems. Bungee location, not shown Environmental door seal, both doors Shock strut Fr\\/ Figure 1. Nose Landing Gear Mechanisms During subsequent nose landing gear retract operations, there was an early indication that the gear uplock mechanism was in the gear-up position. As the shock strut was entering the wheel well and bringing the doors closed, the gear stalled prior to being fully up and locked. After an immediate halt to operations the gear fell freely to the down position. It was observed that the uplock hook was in the gear-up position, thus preventing the uplock roller from engaging. Upon investigation, it was discovered that when hydraulic{'source': 'AMS_2006.pdf', 'page': 128}\",\"Nose Landina Gear Udock Mechanism The Space Shuttle Orbiter\\u2019s nose landing
gear, nose landing gear door, and nose landing gear uplock mechanism, shown in
Figure 1, are interconnected, and must be rigged and operated together.
Following replacement of the door environmental seal, rigging was performed to
achieve proper seal compression. During nose landing gear cycling, the gear
uplock indication did not illuminate because the mechanism did not reach the
full uplock condition. Binding in the rotational fitting between the uplock
fitting and the bellcrank prevented the uplock mechanism from going to the full
over-center position for gear uplock. Measurements of the width of the
bellcrank and the internal width of the fitting showed an interference fit
between the two assemblies. Rework on the bushings per specification
requirements removed the interference condition, allowing the bellcrank to move
freely. Lesson Learned: Proper tolerancing and inspection are critical to
preventing interferences in mechanical systems. Bungee location, not shown
Environmental door seal, both doors Shock strut Fr\\/ Figure 1. Nose Landing
Gear Mechanisms During subsequent nose landing gear retract operations, there
was an early indication that the gear uplock mechanism was in the gear-up
position. As the shock strut was entering the wheel well and bringing the doors
closed, the gear stalled prior to being fully up and locked. After an immediate
halt to operations the gear fell freely to the down position. It was observed
that the uplock hook was in the gear-up position, thus preventing the uplock
roller from engaging. Upon investigation, it was discovered that when
hydraulic{'source': 'AMS_2006.pdf', 'page': 128}\",3,\"Chunks\"],[\"f9764b4a-bd42-11ee-801f-bae7cd9d315f\",3.5726897717,6.7969379425,\"The SRS's of the shock pulses are shown in Figure 6 and the time histories of the pulses are shown in Figure 7. The response of the payload mass was measured with accelerometers at the locations shown in Figure5. The peak response of the mass was measured at the channel 8 (in axis) accelerometer location. The peak response from the shock pulse was peak input value of 805 g's and a peak response of the payload mass was 21.2 g's. This was a reduction of 31 dB. The amount of isolation due to base shock input can be seen by viewing the base input time history on the same plot as the mass response as plotted in Figure 7. The SRS of the 18.1-kg (40-lb) mass to both of the shock pulses is shown in Figure 6. The SRS of the response reflects the fact that, in the higher frequencies, the first input shock pulse is higher and this is reflected in the response of the mass. One noticeable artifact of the mass response in Figure 6 is that there is a peak between 560 Hz and 630 Hz even though the break frequency of both pulses is around 800 Hz. The 630 Hz peak is very close to known surge frequency of the isolator main springs. The sine vibration data only goes to 2 kHz; therefore, the correspondence to the peaks in the SRS data can only be tracked to 2 kHz. Conclusions about the Shock Beam Test Results The following conclusions can be made about the test results. 0 The shock beam test was able to achieve the input levels required by the potential isolation system. The isolators in the bipod configuration were able to decrease mass responses relative to the maximum input by 30 dB or more. These Isolators eat shock!{'source': 'AMS_2006.pdf', 'page': 159}\",\"The SRS's of the shock pulses are shown in Figure 6 and the time histories of
the pulses are shown in Figure 7. The response of the payload mass was
measured with accelerometers at the locations shown in Figure5. The peak
response of the mass was measured at the channel 8 (in axis) accelerometer
location. The peak response from the shock pulse was peak input value of 805
g's and a peak response of the payload mass was 21.2 g's. This was a reduction
of 31 dB. The amount of isolation due to base shock input can be seen by
viewing the base input time history on the same plot as the mass response as
plotted in Figure 7. The SRS of the 18.1-kg (40-lb) mass to both of the shock
pulses is shown in Figure 6. The SRS of the response reflects the fact that, in
the higher frequencies, the first input shock pulse is higher and this is
reflected in the response of the mass. One noticeable artifact of the mass
response in Figure 6 is that there is a peak between 560 Hz and 630 Hz even
though the break frequency of both pulses is around 800 Hz. The 630 Hz peak is
very close to known surge frequency of the isolator main springs. The sine
vibration data only goes to 2 kHz; therefore, the correspondence to the peaks in
the SRS data can only be tracked to 2 kHz. Conclusions about the Shock Beam
Test Results The following conclusions can be made about the test results. 0
The shock beam test was able to achieve the input levels required by the
potential isolation system. The isolators in the bipod configuration were able
to decrease mass responses relative to the maximum input by 30 dB or more.
These Isolators eat shock!{'source': 'AMS_2006.pdf', 'page': 159}\",3,\"Chunks\"],[\"fa0b2d96-bd42-11ee-801f-bae7cd9d315f\",7.4568123817,7.3331599236,\"tool and onto the aft bulkhead of the spacecraft and not the SSRD. Figure 4. SSRD Torque Retention Tool A key feature of the SSRD is it is a mechanically redundant device. It achieves this redundancy because only one of the split spool halves needs to move laterally in order for the rod end to be released. However, this is only true as long as the rod end is not constrained from exiting the unit. In order to maintain mechanical redundancy at the system level, the retraction system needed to be designed such 152{'source': 'AMS_2006.pdf', 'page': 166}\",\"tool and onto the aft bulkhead of the spacecraft and not the SSRD. Figure 4.
SSRD Torque Retention Tool A key feature of the SSRD is it is a mechanically
redundant device. It achieves this redundancy because only one of the split
spool halves needs to move laterally in order for the rod end to be released.
However, this is only true as long as the rod end is not constrained from
exiting the unit. In order to maintain mechanical redundancy at the system
level, the retraction system needed to be designed such 152{'source':
'AMS_2006.pdf', 'page': 166}\",3,\"Chunks\"],[\"fc8c2c96-bd42-11ee-801f-bae7cd9d315f\",4.3813810349,5.9784049988,\"* Large Scale Measurement Device > *\\/ Pane's Base # ,\\/- Frame d . Base (41 Frame Laser Tracker + Laser Tracker Targets Figure 8. SAR Panel Location Measurement Setup The line of sight to these points in the test range is limited due to mechanisms and guardrails in the back of the panels. Different set-ups were required. Figure 8 shows a typical set-up schematic. The measured point positions were finally given in the mechanical build (mb) coordinate system that was predefined. Repeatability of the measurement was verified and the error from nominal position was calculated. The final Laser tracker measurement results of the three-dimensional positional errors are listed in Table 2. The error is defined as the difference between nominal and measured positions. The maximum error calculated is 0.61 mm (0.024 inch) in the X direction. The compound error is attributed to the tolerance of machining and assembly, the relative position of each panel to the reference frame and the measurement set-up accuracy. 340{'source': 'AMS_2006.pdf', 'page': 354}\",\"* Large Scale Measurement Device > *\\/ Pane's Base # ,\\/- Frame d . Base (41
Frame Laser Tracker + Laser Tracker Targets Figure 8. SAR Panel Location
Measurement Setup The line of sight to these points in the test range is
limited due to mechanisms and guardrails in the back of the panels. Different
set-ups were required. Figure 8 shows a typical set-up schematic. The measured
point positions were finally given in the mechanical build (mb) coordinate
system that was predefined. Repeatability of the measurement was verified and
the error from nominal position was calculated. The final Laser tracker
measurement results of the three-dimensional positional errors are listed in
Table 2. The error is defined as the difference between nominal and measured
positions. The maximum error calculated is 0.61 mm (0.024 inch) in the X
direction. The compound error is attributed to the tolerance of machining and
assembly, the relative position of each panel to the reference frame and the
measurement set-up accuracy. 340{'source': 'AMS_2006.pdf', 'page': 354}\",3,\"Chunks\"],[\"ffe5f9f8-bd42-11ee-801f-bae7cd9d315f\",6.9942522049,9.5941085815,\"same length and are stowed coincident with each other. The latches fit in the annular gap between adjacent tubes in a stiffening ring at the lower end of each tube. The adjacent larger tube in turn necks down to a thin stiffening ring at the upper end. The stiffening ring helps to center and align the adjacent smaller tube and to lessen local deformations between the latched segments in bending. Tube Latching Small tapered pins are distributed circumferentially in the stiffening ring at the lower end of each tube. The pins are loaded radially outward by short springs to engage with tapered holes at the upper end of each larger adjacent tube, as shown in Figure 4. When stowed, the springs and pins are compressed by the interior surface of the adjacent larger tube. During Figure 4. Tapered pins used for latching{'source': 'AMS_2012.pdf', 'page': 143}\",\"same length and are stowed coincident with each other. The latches fit in the
annular gap between adjacent tubes in a stiffening ring at the lower end of each
tube. The adjacent larger tube in turn necks down to a thin stiffening ring at
the upper end. The stiffening ring helps to center and align the adjacent
smaller tube and to lessen local deformations between the latched segments in
bending. Tube Latching Small tapered pins are distributed circumferentially in
the stiffening ring at the lower end of each tube. The pins are loaded radially
outward by short springs to engage with tapered holes at the upper end of each
larger adjacent tube, as shown in Figure 4. When stowed, the springs and pins
are compressed by the interior surface of the adjacent larger tube. During
Figure 4. Tapered pins used for latching{'source': 'AMS_2012.pdf', 'page': 143}\",3,\"Chunks\"]]}"
+}
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