In contrast to all existing reaction wheel implementations, an order of magnitude increase in speed can be obtained efficiently if power to the actuators can be recovered. This allows a combined attitude control-energy storage system to be developed with structure mounted reaction wheels. The feasibility of combining reaction wheels with energy storage wwheels is demonstrated. The power required for control torques is a function of wheel speed but this energy is not dissipated; it is stored in the wheel. The I(2)R loss resulting from a given torque is shown to be constant, independent of the design speed of the motor. What remains, in order to efficiently use high speed wheels (essential for energy storage) for control purposes, is to reduce rotational losses to acceptable levels. Progress was made in permanent magnet motor design for high speed operation. Variable field motors offer more control flexibility and efficiency over a broader speed range

Studer, P. A.

English

NASA Technical Reports Server

N85 13874
%.;
I
REACTION WHEELS FOR KINETIC ENERGY STORAGE
Philip A. Studer
NASA Goddard Space F11ght Center
greenbelt, Haryland
329
https://ntrs.nasa.gov/search.jsp?R=19850005565 2020-03-22T17:24:33+00:00Z
. .
ABSTRAC_
In contrast to all existing reaction wheel _mplemencattons, an order of
magnttude increase in speed can be obtained efEtctently If power to the
actuators can be recovered. This will allow a combined attitude
control-energy storage system to be developed with structure mounted
reaction wheels.
Combining reaccton wheels with energy storage wheels may seem an unlikely
marrtage between two elements with opposing requirements. Thls paper will
show that they are not tncompatlble. The power required for control
torques Is a function of wheel_speed but this energy Is not dlssipated; it
is stored In the wheel. The I-R loss resulting from a given torque is
shown to be constant, independent of The design speed of the motor. What
remains, tn order to efficiently use high speed wheels (esseutlal for
energy storage) for control purposes, is to reduce rotational losses to
_cceptable levels.
Progress has been made in permanent magnet motor design for high speed
operation. Variable fleld motors offer more control flexibility and
efficiency over a broader speed range. Resemrch necessary to reach the
goal of efficient ktnetlc energy storage will have generic benefits to
spacecraft attitude control systems and dynamic power systems. (See
fig. 1.)
REA C TION WHEEL S Pot"
AC/ES
ENERGY STORAGE
÷
÷ I
MOTOR
REGENERATIVE TOROUE CONTROL
2
R INDEPENDENT OF SPEED
TECHNOLOGY
+ IRONLESS ARMATURE
+ PERMANENT MAGNETS
+ VARIABLE FIELD-CONSTANT VOLTAGE
Figure 1
330
kREACTION WHEELS FOR KINETIC ENEI_GY STORAGE
Energy storage in flywheels has had a long and successful history in
machines as simple as grandmother's spinning wheel to current automotive
engines. It has recently been studied and found potentially competltlve
for applications in which the desired output is electrical as an alterna-
tive tc electrochemical batteries. Rotating machinery has not had a
significant role in aerospace power systems, whereas attitude control
systems have used flywheels for stabilization and control since the early
days of space flight. Combining these functions could potentially reduce
_he weight of two of the heaviest elements in both of these systems. Power
used for aCtltude control has not been recovered in the past. Brushless DC
motor drives make it possible to recover energy previously lost, improving
system efficiency.
Merging these two subsystem functions and recoverln8 energy used for
control radically change the tradeoffs used tc size and set the speed
limits on reaction wheels. It _rill be shown _hat several improvements in
technology have the effect of raising the optimum design speed of reaction
_eels with a consequent reduction in control system_as_. Likewise, the
further evolutlon of wheel technology necessary to make flywheels compe-
titive with batteries will have a beneficial effect on all future attlt_ie
control systems°
Historically, reaction wheels have been low speed devices. They are
generally operated at nozlnally zero speed and are able to store molentum
by rotating in either direction. The maxlsus.peed is set by the cyclic
mocnenttmexpected in one orbit. The rotational motion of the wheel is a
331
mirror image of the motlon of the spacecraft (or what that Notion would be
i_ unopposed). The amplltude of the angles, rates, and accelerations are
proportloual to the ratio of the £uert_a of the wheel to Inertia of the
spacecraft about the axis of control. The stored momentum is the product
of wheel luertla and angular rate. Therefore, a tradeoff is routlnely run
between Reaction Wheel Assembly (RWA) weight and power as a function of
maximum speed to find a minimum effective weight whlch rill meet the
mission momentum requirement. (See fi E. 2.)
REA_.CTION WHEEL OPTIMIZATION
X=POWER." -WEIGHTjO--WEIj2,HT+E.QU]V_.._WEIGHT _2.F. POW...F...R
TOTAL WT '_f f
F_
--_31 /
POWER //
RWA WT./ _ POWER
,100 200
40(D 800' 16..00, , 320_) PAD.
DESIGN SPEED > SEC.
¥1s_re 2
332
i\
!
i
!
This proportlonallty between power and _xi_um speed is based on the
physical law relating power to speed and torque ({tgure 2). The motor
constant _, torque per ampere, is equal to KV, volts per red/set. We
cannot change these physical relaC£onships bu_ ue note Chac Chls energy is
not dissipated, it is stored in the wheel. In the case of a combined
a_titude control/energy storage (ACES) system, ue _ave simply transferred
energy from one storage element to another where it remains avellable to
the power system. Since reaction wheel control handles cyclic torques, the
wheel _rlll be called on to slo_ down as often as co accelerate. The dr_ve
must be a motor/generator to efficiently recover the stored energy and
transfer 11 to the spacecraft electrical load. The permanent magnet dc
motor is an efficient transducer, it behaves equally we21 as a generator
sad as a motor. This power recovery has not generally been implemented in
spacecraft control systems because the energy was relatively small and the
voltage variation was 100 percent, making efficient recovery very
dlfflcalt. For high speed energy storage _heels, the energy Involved will
be larger and the voltage varlatlon much smaller.
The efflclent transfer of power requlres a careful look at the amount
of power dissipated in the process. As we have seen earller, the motor
constant KT decreases in proportion to the increased no-lo_d speed o£ the
nmtor. At first glance, ao order of magnitude increase in the current to
produce a given _orque looks alarming, recogntzir_ thst I2R is the power
dissipated,
333
®
/However, (flgure 3) the number of turns (armature conductors) necessary
to achieve _ and KT axe tracer by the same p_oport£on. Also, _ the motor
in question is the same size, the d£aneter of the conductors can also be
12
proportlonally £ncreased. Therefore, R decreases as fast as increases
and the £nternal dlaslpatlon Is the same for all design speed ranges.
ARMATURE DISSIPA TION
.-._ DESI2RIGIV_/2SPEED //
/
+ +
DESIGN SPEEDj RAD/SEC
_r
Fi_p_e 3
A more difficult eha].leuge ls posed by the rotattonnl losses. At peak
efficteucy the cocatloual loss_.s are equal to the I2R losses (ftgure 3).
Furthermore, these are not all linearly related to speed. There are
colponeats _ch are speed ludependeut, such as hysteresis in motor
l_ninatlous, and some _'h£ch increase faster than the square of the speed
su(:h as v_udal_. It is uee.essat'y to 2soLate aud el:LeL1Luate as many sources
of paras£tlc loss as posslble if effLc£eut hlgh speed operation is to be
achleved (1). There fOllo_m a l£at of 1ossea not associated v£th pom_r Into
or ouc of a dc uotor generator (see f:L8. 4):
J J4
SOURCES:
ROTATIONAL LOSSES
SOLUTIONS:
BRUSHES,
MECH.
ELEC. .POWER FErS
WrNDAGE, VACUUM
"CORE"LOSSES,
HYSTERESIS
JRONLESS ARMATURE
EDDY CURRENTS
ARMATURE,
EDDY CURRENTS "UWZ'_RE
CIRCULATING C UR RENTS_.___."WYE"WlNDING
Figure 4
Electronic co_lutation has eliminated the mechanlcal drag torque
associated wlth carbon brushes. There are electrical losses due to leakage
currents in power switches and diodes, logic circuit power drain, and rotor
position sensors. All of these occur independent of the power demand on
the motor/generator. They are also Inaependent of the operatlnE speed of
the motor and trill not be consldered further here.
_indage loss £s extremely speed dependent; but the solution is
straightforward. Reduction of enclosure pressure to 10 -5 tort can make
this loss negligible over the entire speed range.
Bearing drag torques for m_chanical bearings have both coulomb and
viscous components. The power loss is therefore proportional partly to
speed and partly to the square of wheel speed. Magnetic bearings offer
somewhat lower torques having the same effects due to hysteresis and eddy
currents. Treating magnetic bearing torques adequately would require a full
discussion in another paper. ¥or the purpose of this dLqeussion, let us
;sume that the 1>earing torque loss can be held to small enough levels so
as not to drive the choice of operatlug speed.
335
For conventional dc motors, the hysteresis and eddy current losses are
much larger than bearing losses for the power and torque levels required
for elther energy storage or reaction wheel control. These losses occur in
the laminated magnetically soft iron into whlch the armature conductors are
wound. Although the potential of newly developed amorphous steel alloys,
such as Metgas (a trademark of Allied Corp.), have not been fully explored,
the power losses of this type of motor would likely be prohibitively high
at the upper end of the speed range.
Fortunately another dc motor construction is available. These so-
called "ironless armature" dc motors have the armature conductors in the
(2)
_agnettc air gap (figure 5).
MOTOR ARMATURE (IRONLESS)
MAGNETIC BEARING STATOR
PERMANENT MAGNET SrnCo 5 MOTOR ROTOR
& MAGNETIC BEARING .SUSPENSION RING
Figure 5
336
, :..,_- . " .•'.2
The entire "iron" and permanent magnet fleld assembly is on the rotor
and there is no relative motion between it and any stationary iron.
Therefore, there is no hysteresis loss. There remains eddy current loss
within the armature conductors themselves, but even this can be reduced by
known methods such as subdividing each conductor into finer strands ("lltz"
wire) (3). Further Eelns can be expected by pole shaping to make the field
pole flux vary slnusoldally since the flux gradlen_ creates the eddy
currents. Neither of these techniques drastically affects the performance
or sizing of the motor. Therefore: very hlgh efficiency, high speed motor
design can be approached with confidence when the necessary analytical and
experimental resources are applied.
There are a few other sources of parasitic power losses such as
circulating currents within the armature windings and eddy currents in
various structural and mechanical parts whlch require careful engineering
attenclon because they are generally ignored in less demanding
applications.
a
|
:1 _--- I T
I MAGNET I_"vELOIIN4_ _ u
.+:! -.
:.! _  \AI
- _ _ _ m. _ l
I g83
Figure 6
33"/
[ . I .... i_ I
Permanent n_gn_t motors have improved slgnificantly in the past 25
years (figure 6) and each of these steps has allowed efficient operation at
a higher speed reglme. Hlgber speed puts more energy Into a smaller
1£ghter package. This has a visible _mpact tu attitude control
technologyNthe NO_ series of spacecraft utilize brushless dc reaction
wheels wi_h a no-load speed o£ I0,000 RPH. Neither ironless armature
motors nor magnetlc bearings have ye_ been applled to flight spacecraft
systems by Amerlcan aerospace manufacturers. In splte of many feasibility
demon_eratlous, the required depth of englueerlng analysls and design has
no_ been applied. However, given the technology program needed to
accomplish the kinetic energy storage task, generic Improvements in
attitude control systems will result.
AIZ of The earZier discussion focused on permanent _mgnet _o_ors.
_ould field motors o£fer greater control _lexlbillty, _he ability to vary
the peak of the efflclency polnt to match the load, and produce conslant
voXtage over a range of speeds. (See fig. 7.)
338
I
EFF?CIENCY-
PERMANENT MAGNET AND VARIARtF" FIELD MQTORS
FIELD CONTROL _.
,
,-7" ",, \ff_; =KvCIO w
OPERATING SPEED w , ,, i)
Figure 7
®
This technology was explored briefly in the 1960's and is applicable to
combined energy storage and attitude control systems. The value of _ound
field motors Increases at higher power levels now being considered. NASA
owns the patents on this design approach (4'5)" Tc improve balance stability
both the field and the armature _rlndings are on the staror. The rotor is
entirely a magnetically soft ferro-magnettc alloy, which has the requisite
strength properties for use on energy storage wheels. Since the field flux
is induced into =he rotor via an auxiliary airgap(s), the magnetic
suspension can be integrated into the motor design vtth a sizeable veight
savings since they utilize a common "_ron" path. Integration of these two
prime functions adds a significant challenge to the engineering design
task. The payoff is a vastly superior product.
In conclusion, the GSFC is already operacir_ reaction wheels in space
with good reliability at speeds as high as 10,000 RPH. The technological
path which _rlll allow quadrupling this speed to make kinetic energy storage
competitive _th electrochemical systems has already been charted. If the
decision is made to proceed _,_th development and use of ACES, a st_n_iftcant
advance will be achieved in two primary spacecraft subsystems. If the
United States does not meet this challenge, someone else will; the
Europeans (6) and the Japanese (7) are already proceedtng_rlth developments
of energy storage flywheels.
Efficient recovery of the energy stored in a flywheel is implicit tu a
kinetic energy storage systes. When this mode o£ operation Is incorporated
into the reactlon_heel s_z£ng and speed selection tradeoff_, much
different results are obtained.
II
q
• i
339
The technological development program Co make efficient reliable energy
storage wheels will have substantial intermediate benefits in attitude
control and dynamlc power systems generally. Power efE1clent lightweight
hlgh-speed control and momentum storage wheels will improve spacecraft
"bus" performance, increasing payload mass fraction and available power for
instruments° Combining the functions of control actuators and energy
storage as in ACES focuses the technology on two oE the more massive
elements in spaceer&_t and car be of particular value in large scale long-
life systems where resource sharlnE, distributed control, and unlimited
cycle life are essential.
REFERENCES
1. Kuhlman, John R.: Design of Electrical Apparatus, Third ed., chap. 7, J. Wiley
& Sons, _nc., 1950.
2. Scuder, P. A.: A New DC Torque Motor. Second Int. Workshop on R.E. Cobalt
Magnet Applications, Univ. of Dayton, Dayton, Ohio, June 8-11, 1976.
3. Roters, Herbert C.: Elec_roma_etic Devices. J. W_ley & Sons, Inc., 1941.
&. Studer, P. A.: Direct Current Motor Wi_h Stationary Armature and Field. U.S.
Patent 3,569,80&, Aug. 1968.
5. Studer, P.A.: Electric Motive Machine Including MaEnetic Bearing. U.S.
Patent 3,694,041, Jan. 1971.
6. Napolitano, L. G.: Space 2000. 33rd Int. Astronautical Congress , Paris,
France, Sept. 27 - Oct. 2, 1982.
7. Murakami, C.: Development Activity on MaEnetic Bearings for Space Use in
the National Aerospace Lab of Japan. Sixth Int. Workshop on R.E. Cobalt
}_Enet Applications, Baden/Vienna, Austria, Aug. 31 - Sept. 3, 1982.
340


Reaction wheels for kinetic energy storage

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