Split Stirling linear cryogenic cooler for a new generation of high temperature infrared imagers A Veprik, S Zehtzer and N Pundak Ricor, Cryogenic and Vacuum Systems, En Harod, 18960, Israel ABSTRACT Split linear cryocoolers find use in a variety of infrared equipment installed in airborne, heliborne, marine and vehicular platforms along with hand held and ground fixed applications. An upcoming generation of portable, high-definition night vision imagers will rely on the high-temperature infrared detectors, operating at elevated temperatures, ranging from 95K to 200K, while being able to show the performance indices comparable with these of their traditional 77K competitors. Recent technological advances in industrial development of such high-temperature detectors initialized attempts for developing compact split Stirling linear cryogenic coolers. Their known advantages, as compared to the rotary integral coolers, are superior flexibility in the system packaging, constant and relatively high driving frequency, lower wideband vibration export, unsurpassed reliability and aural stealth. Unfortunately, such off-the-shelf available linear cryogenic coolers still cannot compete with rotary integral rivals in terms of size, weight and power consumption. Ricor developed the smallest in the range, 1W@95K, linear split Stirling cryogenic cooler for demanding infrared applications, where power consumption, compactness, vibration, aural noise and ownership costs are of concern. Keywords: high temperature infrared detector, compact infrared imager, split Stirling linear cooler, vibration, aural noise, reliability. 1. INTRODUCTION Infrared (IR) imagers play a vital role in the modern tactics of carrying out surveillance, reconnaissance, targeting and navigation operations. By converting the thermal battlefield into dynamic visual imagery, such equipment dramatically enhances the observation and command control capabilities of the leaders of combat infantry and Special Forces. In spite of the recent advances and widespread use of uncooled infrared detectors, it is still generally accepted that the “best technology for true IR heat detection is the cooled detector” [1]. They are superior to the uncooled competitors in terms of working ranges, resolution and ability in detecting/tracking fast moving objects in dynamic infrared scenes. The superior performance of such imagers is achieved by using novel optronic technologies along with maintaining the IR focal plane arrays (FPA) at cryogenic temperatures (77K, typically) using microminiature Stirling cycle cryogenic coolers. Over the past few years industrial progress has led to the development of a new InAlSb diode technology relying on Antimonide Based Compound Semiconductors (ABCS), offering lower dark currents or higher operating temperatures (being in the 100K region) [2]. The SWIR MCT technology [3] offers the possibility of operating a FPA at even higher temperatures, in excess of 200 K. The authors of [4] report on a 320×256 middle-wavelength infrared focal plane array based on InAs quantum-dot/InGaAs quantum-well/InAlAs barrier detector operating at temperatures of up to 200K. The direct benefits of using such high temperature IR FPAs are the lowering of the cooling constraints resulting in a simplified system design, using smaller and more cost effective, long life cryocoolers which typically consume less electrical power and show faster cool-down times. Traditionally, integral rotary cryogenic coolers were used for maintaining the, such as above, IR FPA at optimal cryogenic temperatures. As compared to their military off-the-shelf linear competitors they were lighter, more compact and normally had better electromechanical performance. However, their inherent drawbacks, such as high wideband vibration export and limited lifespan spurred the development of the microminiature linear Stirling cryogenic coolers. These novel, long-life, acoustically and dynamically quiet cryogenic coolers, while being superior in many respects, need to be comparable to the above rotary cryocoolers in terms of bulk, power consumption and ownership costs. An additional advantage of the linear cryocoolers, as compared with their rotary rivals, should be that, at least in theory, they might operate at elevated driving frequencies without affecting their overall life span. Unfortunately, such coolers are still not off-the-shelf available; the existing linear tactical coolers are too oversized/overweight and power-thirsty for the above purposes.
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Split Stirling linear cryogenic cooler for a new generation of high
temperature infrared imagers
A Veprik, S Zehtzer and N Pundak
Ricor, Cryogenic and Vacuum Systems, En Harod, 18960, Israel
ABSTRACT
Split linear cryocoolers find use in a variety of infrared equipment installed in airborne, heliborne, marine and vehicular
platforms along with hand held and ground fixed applications. An upcoming generation of portable, high-definition night
vision imagers will rely on the high-temperature infrared detectors, operating at elevated temperatures, ranging from 95K
to 200K, while being able to show the performance indices comparable with these of their traditional 77K competitors.
Recent technological advances in industrial development of such high-temperature detectors initialized attempts for
developing compact split Stirling linear cryogenic coolers. Their known advantages, as compared to the rotary integral
coolers, are superior flexibility in the system packaging, constant and relatively high driving frequency, lower wideband
vibration export, unsurpassed reliability and aural stealth. Unfortunately, such off-the-shelf available linear cryogenic
coolers still cannot compete with rotary integral rivals in terms of size, weight and power consumption.
Ricor developed the smallest in the range, 1W@95K, linear split Stirling cryogenic cooler for demanding infrared
applications, where power consumption, compactness, vibration, aural noise and ownership costs are of concern.
Keywords: high temperature infrared detector, compact infrared imager, split Stirling linear cooler, vibration, aural
noise, reliability.
1. INTRODUCTION
Infrared (IR) imagers play a vital role in the modern tactics of carrying out surveillance, reconnaissance, targeting and
navigation operations. By converting the thermal battlefield into dynamic visual imagery, such equipment dramatically
enhances the observation and command control capabilities of the leaders of combat infantry and Special Forces.
In spite of the recent advances and widespread use of uncooled infrared detectors, it is still generally accepted that the
“best technology for true IR heat detection is the cooled detector” [1]. They are superior to the uncooled competitors in
terms of working ranges, resolution and ability in detecting/tracking fast moving objects in dynamic infrared scenes.
The superior performance of such imagers is achieved by using novel optronic technologies along with maintaining the
IR focal plane arrays (FPA) at cryogenic temperatures (77K, typically) using microminiature Stirling cycle cryogenic
coolers.
Over the past few years industrial progress has led to the development of a new InAlSb diode technology relying on
Antimonide Based Compound Semiconductors (ABCS), offering lower dark currents or higher operating temperatures
(being in the 100K region) [2]. The SWIR MCT technology [3] offers the possibility of operating a FPA at even higher
temperatures, in excess of 200 K. The authors of [4] report on a 320×256 middle-wavelength infrared focal plane array
based on InAs quantum-dot/InGaAs quantum-well/InAlAs barrier detector operating at temperatures of up to 200K.
The direct benefits of using such high temperature IR FPAs are the lowering of the cooling constraints resulting in a
simplified system design, using smaller and more cost effective, long life cryocoolers which typically consume less
electrical power and show faster cool-down times.
Traditionally, integral rotary cryogenic coolers were used for maintaining the, such as above, IR FPA at optimal
cryogenic temperatures. As compared to their military off-the-shelf linear competitors they were lighter, more compact
and normally had better electromechanical performance. However, their inherent drawbacks, such as high wideband
vibration export and limited lifespan spurred the development of the microminiature linear Stirling cryogenic coolers.
These novel, long-life, acoustically and dynamically quiet cryogenic coolers, while being superior in many respects,
need to be comparable to the above rotary cryocoolers in terms of bulk, power consumption and ownership costs. An
additional advantage of the linear cryocoolers, as compared with their rotary rivals, should be that, at least in theory, they
might operate at elevated driving frequencies without affecting their overall life span. Unfortunately, such coolers are
still not off-the-shelf available; the existing linear tactical coolers are too oversized/overweight and power-thirsty for the
above purposes.
The authors report on the successful development of a novel Ricor
model K527 microminiature 1W@95K split Stirling linear
cryogenic cooler [5], which was designed to provide cryogenic
cooling to a wide range of forthcoming infrared imagers, where
power consumption, compactness, vibration, aural noise and
ownership costs are of concern. The cooler, as shown in Figure 1,
comprises "moving magnet" resonant piston compressor and
pneumatically driven expander connected by a flexible transfer
line .
2. K527 EXPANDER UNIT
The expander unit comprises a "mass-spring", pneumatically
driven displacer-regenerator, as is wide accepted across the
industry. As is known, it is favorable to design such a displacer-
regenerator so that to operate it at or near its resonant frequency.
The first benefit of such a resonant tuning is that the displacer
stroke reaches its maximum at given pneumatic force delivered by the compressor, or alternatively, the desired displacer
stroke may be obtained at minimum pneumatic force delivery. The second benefit is that tuning the displacer to resonate
delivers almost automatically the desired 90º phase lag between the pressure pulses arriving through the transfer line
from the compression space and the displacer motion, as needed for producing maximum cooling effect [6]. The above
two benefits contributes essentially to increasing the displacer's expansion work at given acoustic work delivered by a
compressor. Resulting from this is improved heat pumping effect from the expansion space to which the heat payload is
thermally linked. Since the spring effect of equivalent gaso-dynamic visco-elastic loading in expander is negligibly
small, the inertia of the moving assembly and the equivalent elasticity of the above-mentioned spring define the
closeness to the resonance condition. There are two different approaches to forming the above "spring" component. In
the first approach, helical wire spring or, alternatively, two counter-facing preloaded helical wire springs are arranged as
to link the stationary housing with the movable displacer-regenerator assembly. Using mechanical spring yields compact
design and convenient resonant tuning which appears to be almost independent on environmental temperature. The
inherent disadvantages of such a design are unreliable mechanical spring connection, radiation of acoustic noise, tiny
metal debris generation and, most important, exertion of large side forces on dynamic seals leading to excessive friction,
parasitic losses, tear and wear.
In another implementation, a "pneumatic pillow" [6] may be formed by the plunger tail cyclically protruding the sealed
rear space. This approach is widely accepted across the industry because of the compactness and almost frictionless
operation. Unfortunately, the rate of such a pneumatic spring appears to be a function not only of the rear space volume
and plunger area, but also of average pressure and environmental temperature having strong influence on the above
resonant frequency. The additional disadvantage is excessive overheating of the cold finger housing because of the
irreversible compression losses associated with cyclic compression of the particular portion of gas sealed inside the rear
space, forming the above "gas pillow".
In the present design, the authors capitalize on using the highly accurate double starting helix machined spring with
integral retainers [7]. The high mechanical accuracy has been achieved through the fine machining of the spring blanks
followed by a CNC assisted electro-discharge machining the flexure slot.
(b)
Figure 2. Schematic and external layout of a pneumatically driven expander
Expansion space
Cold finger
Stepped driving plunger
Bushing Hot space Machined spring
Transfer line Rear space Housing
Figure 1. K527 split Stirling linear cryogenic cooler
(a)
Displacer-regenerator
The self-explanatory Figure 2 shows the schematics (a) and the external layout (b) of the pneumatically driven sprung
expander. In Figure 2, the displacer-regenerator comprising a stack of stainless steel mesh disks of optimized geometry
and porosity is attached to the stepped plunger and arranged so as to slide freely inside the accurately aligned bushing
and thin-walled cold finger made of stainless steel.
The above explained machine double-helix spring is placed inside the rear space. One of the spring ends is attached to
the stationary bushing and the other to the movable plunger tail, thus forming almost friction-free design.
3. K527 LINEAR COMPRESSOR (SINGLE-PISTON VS DUAL PISTON)
As is known, the single-piston compressor is a powerful source of vibration export at driving frequency and higher-order
harmonics [8]. It is widely accepted, therefore, that dual-piston, should-be dynamically counterbalanced, compressor is
the only solution of choice for the inherently vibration sensitive cooled IR applications. The major cryogenic coolers
vendors like Thales, AIM, Carleton, DRS, Raytheon, etc. are manufacturing microminiature (below 1.5W@77K) split
conditioner and Data Physics QUATTRO signal analyzer. Figure
7 shows the K527 cryogenic cooler mounted upon the above
dynamometer, where compressor and cold head axis are directed
as to coincide with dynamometer axis, thus allowing independent
measurement of vibration export in compressor and expander
axis. Figures 8.a,b show the typical spectra of vibration export
produced by the compressor and cold head. From Figure 8, the
vibration export comprises well pronounced driving frequency
component 12N@75Hz (compressor) 2N@75Hz (cold head) and
along with low magnitude higher order harmonics. The radial
vibration export is negligibly small in both cases. From Figure 8,
the vibration export produced by such a compressor in a typical
tactical application has a potential to cause a harmful line-of-
sight-jitter, low frequency noise, high frequency microphonics,
etc. and, therefore, needs to be closely controlled. At the same
time, the vibration export produced by the expander is essentially
lower as compared to this of compressor and is considered to be
adequate to allow rigid mounting of such an expander to an optical bench or imager enclosure, as needed for the optical
stability, heat sinking, etc.
0.001
0.01
0.1
1
10
100
0
10
0
20
0
30
0
40
0
50
0
60
0
70
0
80
0
90
0
100
0
Frequency, Hz
Vib
ration
exp
ort
, N
(a)
0.0001
0.001
0.01
0.1
1
10
0
100
200
300
400
500
600
700
800
900
1000
Frequency, Hz
Vib
ration
exp
ort
, N
(b)
Figure 8. Vibration export produced by K527 cryogenic cooler in a typical temperature control mode.
One of the objectives of the current paper is to show the system designer that attenuation of vibration export produced by
the single-piston compressor of a split Stirling cryogenic cooler is not something of black art and is quite doable within
tight restraints imposed on size, weight and heatsinking performances.
As different from the case of counterbalanced dual-piston compressor, there is no universal recipe to designing vibration
protective and heat conductive arrangement. In each particular application case, this requires individual consideration.
The proper use of the below disclosed principles allows the system designer to do so without affecting cryocooler size,
weight and performances.
Heavy and rigid instrument.
To start with, let us consider the case when such a cryocooler is used inside heavy and rigid instrument, or, alternatively,
the instrument is mounted rigidly to a heavy and rigid platform. On this occasion, because of the large inertia and
stiffness, the vibration export will not be an issue at all. In this case it is recommended to clamp the compressor casing to
the system shield or the optical bench using thin (0.5 - 1mm) layer of thermo-conductive material. This is needed for
tolerance compensation, high frequency noise protection and efficient heat sinking.
Instrumentation operating in harsh environmental conditions.
In applications undergoing frequent exposure to harsh environmental extremes like random and sine vibration and no
vibration isolation is provided, the vibration exerted by the environment will be more intensive than this produced by the
compressor unit. The same mounting principle, as explained above is applicable.
Lightweight instrumentation operating in mild environmental conditions
These are hand-held, ground fixed portable and vibration isolated gyro-stabilized IR imagers. The optical performances
of the above listed equipment will be affected by the above mentioned massive vibration export, the suppression of
which may be achieved, even within a stringent weight and size budget, by combining the principles of vibration
isolation and tuned dynamic absorber, as explained in [14]. In this approach, the compressor is clamped to the imager
casing or the optical bench through a compliant vibration mount for attenuation of high frequency portion of vibration
export and a tuned dynamic absorber should be mounted coaxially on the compressor housing for suppressing the
vibration export at the driving frequency. The use of the tuned dynamic absorber becomes possible since the driving
frequency is essentially constant and may be adjusted and maintained with a very high accuracy, 0.01Hz, typically. The
heatsinking may rely on heat conductivity of compliant heat link/pipe or natural/ forced convection using the finned
radiator and micro-fan.
6.2. DYNAMIC MODEL AND EQUATIONS OF MOTION
In Figure 9, the 3-degree of freedom system schematically represents the relevant dynamic model. In particular,
1 2 3, ,M M M represent the masses of the system platform, compressor housing and tuned dynamic absorber, respectively.
Further, 1 1,K B represents the stiffness and damping of compliant mounting
to the stationary ground, 2 2,K B represents stiffness and damping of
vibration mounting of compressor and 3 3,K B represents the stiffness and
damping of the spring to support the dynamic absorber. The time function
( )r t represents actual vibration export, the spectrum of which is shown in
Figure 8.a. Resulting from the action of this force are dynamic deflections
1 2 3, ,x x x measured from appropriate positions of static equilibrium. This
model describes all possible cases of system and compressor mountings.
The differential equations of motion take the form
( ) ( )( ) ( ) ( ) ( ) ( )( ) ( )
1 1 1 1 1 1 2 1 2 2 1 2
2 2 2 2 1 2 2 1 3 2 3 3 2 3
3 3 3 3 2 3 3 2
0
0
M x K x B x K x x B x x
M x K x x B x x K x x B x x r t
M x K x x B x x
+ + + − + − =
+ − + − + − + − =
+ − + − =
(1)
Using complex Fourier transform, ( ) ( ) j tG j g t e dt
ωω∞
−
−∞
= ∫ , where ω is
angular frequency and 1j = − is complex unity, we make a transition
from time into a frequency domain
( ) ( ) ( ) ( ) ( ) ( ) ( ) ( )1 1 2 2 3 3; ; ; x t X j x t X j x t X j r t R jω ω ω ω⇔ ⇔ ⇔ ⇔
substitute into (1) and obtain instead of the set of differential equations the set of linear equations
1M
2M
3M
2 2,K B
1 1,K B
( )3x t
( )r t
Compressor
Platform
3 3,K B
Tuned dynamic absorber
Figure 9. Dynamic model
( )2x t
( )1x t
Ground
( ) ( )( ) ( ) ( ) ( ) ( )
( ) ( )
1 1 1 1 1 1 2 1 2 2 1 2
2 2 2 2 1 2 2 1 3 2 3 3 2 3
3 3 3 3 2 3 3 2
0
0
M X K X B X K X X B X X
M X K X X B X X K X X B X X R j
M X K X X B X X
ω
+ + + − + − =
+ − + − + − + − =
+ − + − =
(2)
The solution to (2) is trivial using, for example, the Cramer's rule. In particular, we find the complex frequency response
function (receptance) relating the dynamic response of the platform and the force applied to the compressor housing, this
is:
( ) ( )( )
( )( )( ) ( )
( ) ( ) ( )( )
2
2 2 3 3 31
1 2
1 1 2 1 2 2 2
2
2 2 2 3 2 3 2 3 3
2
3 3 3 3 3
0
0
K j B M K j BX jH j
R j M K K j B B K j B
K j B M K K j B B K j B
K j B M K j B
ω ω ωωω
ω ω ω ωω ω ω ω
ω ω ω
+ − + += =
− + + + + − +
− + − + + + + − +
− + − + +
(3)
From (3), setting 2
3 3M Kω = and
30B → , minimizes the magnitude of the above FRF at particular driving frequency
ω , i.e. the dynamic response of the base may approach zero independently on other system parameters. The above
explains the operational principle of tuned dynamic absorber, which needs to be "tuned" such as to have resonant
frequency equal exactly the driving frequency, e.g. 3 3 3
K M ωΩ = = . In practice, it is easier to adjust the driving
frequency to the above resonant frequency of tuned dynamic absorber. The complex frequency response function (3)
covers all the possible cases of systems design.
Study case 1. Portable hand held IR imager with vibration-mounted compressor
For numerical calculations in this case we accepted that the mass of the imager (excluding compressor and dynamic
absorber) is 1
3M kg= . The masses of compressor and dynamic absorber are 2
0.2M kg= and 3
0.1M kg= ,
respectively. This case will be also characterized by the low frequency primary vibration isolator mimicking the
dynamic compliance of the human upper limbs firmly holding the IR imager; these are
1 1 120 (10 )K M rad s HzπΩ = = and
1 1 1 12 0.1B Mζ = Ω = .
1.E-09
1.E-08
1.E-07
1.E-06
1.E-05
1.E-04
20
30
40
50
60
70
80
90
100
110
120
130
140
150
160
170
180
190
200
Frequency, Hz
|H1(j
ω)|
, m
/N
15Hz
50Hz
Reference
20 Hz
Hz25 Hz
Hz30 Hz
Hz35 Hz
Hz
40 Hz
Hz 45 Hz
Hz
0
100
200
300
400
500
600
700
800
15 25 35 45
Resonant frequency of vibration mount, Hz
Supre
ssio
n r
atio
(a) (b)
Figure 10. Performance of tuned dynamic absorber
Figure 11. Exploded view of tuned dynamic absorber
The dynamic absorber is assumed to be tuned to the fixed driving
frequency 75Hz and has typical low damping ratio 0.35%; namely
3 3 3150K M rad sπΩ = = and
3 3 3 32 0.0035B Mζ = Ω = . In all
the calculations we also accepted the case of moderately damped
vibration mount characterized by the damping ratio
2 2 2 22 0.15B Mζ = Ω = .
Figure 10.a shows the spectra of the modules of the system
receptances at different resonant frequencies of compressor
vibration mounting over the frequency range 20-200Hz; also
shown is the reference case (rigid compressor mounting and no
dynamic absorber). From Figure 10.a, at driving frequency 75Hz
we observe deep and wide antiresonant notches, the depth and
width of which depend strongly on the above resonant frequency,
namely, the softer compressor mounting yields better suppression
ratio (as compared with the reference case) and the frequency
tuning will be more convenient. In Figure 10.b, solid curve shows
dependence of this suppression ratio on the above resonant frequency. From Figure 10.b, using reasonably soft and
damped vibration mount allows achieving very impressive suppression ratios typically over-performing this attainable by
the actively assisted counterbalancing of dual-piston compressors.
(a) Assembled view
(b) Exploded view
Figure 12. Vibration mounting of a linear compressor.
(c) Finned radiator for forced convection
(d) Heat conductive thermal link
Figure 13. Heat sinking options
In a practical implementation, the exploded view of which is shown in Figure 11, the tuned dynamic absorber may
comprise heavy inertial ring (made of Tungsten for compactness) which is clamped between two sets of flat flexural
bearings separated by spacers for eliminating damping effects associated with dry friction between adjacent
springs. As it was already stated above, the vibration export produced by the single piston compressor is primarily axial
and negligibly small in radial direction, the single degree of freedom vibration mount of compressor to the IR imager
will be adequate.
Figure 12.a shows one of the possible implementations of such a single degree of freedom vibration mount relying on a
set of two sets of flat metal springs supporting linear compressor. Using stacked metal flat springs provides for desired
damping in compressor's vibration mount and eliminates parasitic degrees of freedom, as needed for mechanical
stability. The tuned dynamic absorber is mounted inline with compressor. Figure 12.b shows the exploded view.
Experimentation
Figure 14 shows the experimental set-up, where
vibration mounted compressor carrying 100gr
tuned dynamic absorber is mounted upon the 3kg
baseplate mimicking the inertia or the above
mentioned IR imager which in turn is placed
upon soft sponge to reproduce the case of low
frequency vibration mounting. The vibration of
the base plate was measured using miniature
Bruel@Kjaer Type 4394 accelerometer. The
curvefitting of the experimentally obtained
absolute transmissibility has shown the resonant
frequency 75Hz and a typical 0.35% damping
ratio.
Figure 15.a,b show the superimposed spectra of
the base absolute acceleration and relative
displacement for the reference case and for the case of vibration mount of compressor having resonant frequency 40Hz.
In this experimentation, the expander was mounted separately with purpose of eliminating its interference.
1.E-03
1.E-02
1.E-01
1.E+00
1.E+01
1.E+02
1.E+03
0
100
200
300
400
500
600
700
800
900
1000
Frequency, Hz
Basep
late
vib
ratio
n,
mg
Reference
40Hz
1.E-07
1.E-06
1.E-05
1.E-04
1.E-03
1.E-02
1.E-01
1.E+00
1.E+01
0 200 400 600 800 1000
Frequency, Hz
Base
pla
te v
ibra
tion,
µm
Reference
40Hz
(a) (b)
Figure 15. Platform vibration
Figure 14. Experimental setup
From Figure 15, in the reference case the working cryocooler produces a vibration export mostly at the driving
frequency. The magnitude of the primary harmonic is 367 mg; the secondary harmonic is 46-fold smaller – 8 mg. Low
powered higher frequency content is also seen up to 1000Hz. Making use of the above explained tuned dynamic absorber
produces 175-fold vibration attenuation at driving frequency which correlates well with theoretical prediction in Figure
6. Along with these lines, we observe massive vibration attenuation over the high frequency range; this may be attributed
to the action of low frequency vibration mount.
It is important to note that this significant
vibration attenuation has been obtained using a
very light dynamic absorber, the weight of
which is only 3% relative to the entire system.
Further improvement (if needed) may be easily
achieved by incorporating a slightly heavier
tuned dynamic absorber.
The experimentation was also performed for
different vibration mounting of compressor.
The obtained suppression ratios strictly follow
prediction in Figure 10.b; the experimentally
obtained points are marked as circles.
It is important to notice that after such a
massive suppression of vibration export
produced by the compressor, the cold head
appears to be the major source of vibration
disturbance. However, the vibration export
produced by the cold head results in a vibration
of the entire imager occurring primarily in a
direction which is normal to FPA. Because of
the typically essential focus depth, the imager
may tolerate this sort of mechanical disturbance without developing excessive imagery blur. In case of super sensitive IR
equipment, the authors strongly recommend using additional (smaller) tuned dynamic absorber mounted inline with the
cold head, as shown in Figure 16, where from experiment the vibration of platform plate was below 2mg@75Hz in all
directions.
Study case 2. Portable hand held IR imager with rigidly mounted compressor Sometimes restrictions imposed on the imager internal packaging, weight and heat sinking do not allow using
compressor vibration mounting. This case is typical for the lightweight systems (ultra portable handheld and
gyrostabilised imagers as used in UAVs). On this occasion, because of the small imager weight, the compressor might be
mounted rigidly and tuned dynamic absorber will suppress the base-plate vibration directly. The expression for the
magnitude ( )3H Ω at working frequency in case of rigidly mounted compressor may be easily reduced from (3), this is
( )1
2 2 2 2
3 3 1 3 34H M M ζ
− Ω ≈ Ω +
(4)
From (4) follows that for the light platforms, 2 2 2
1 3 34M M ζ<< , its vibration at antiresonance is defined primarily by the
mass of dynamic absorber and damping ratio, this is: ( )3 3 32H MζΩ ≈ ; the suppression ratio at antiresonance is,
therefore, 3 3 1
2M Mη ζ= . From the above, for the relatively light hand held imagers, the vibration suppression level is
primarily defined by the mass ratio 3 1
M M and the damping ratio 3 3 3 3
2B Mζ = Ω . This gives clear indication how
heavy the dynamic absorber should be to provide the required vibration suppression at given damping ratio. It is
important to notice that, from practice, heavier tuned dynamic absorbers normally show lower damping ratios.
7. COMPARISON WITH COMPETITORS
The self-explanatory Table 1 compares dimensions, weights, vibration export and MTTFs of the typical dual-piston
compressors of microminiature split Stirling cryogenic coolers offered by world leading vendors.
Figure 16. Using two dynamic absorbers is super-sensitive equipment
0
10
20
30
40
50
60
100
300
500
700
900
11
00
Total heat lift, mW
Pow
er
con
sum
ption, W
DC
SF070B (AIM), DC SF100A (AIM), DCSF100B (AIM), DC SL100(AIM) DCLC1040 (Carleton), DC LC1047 (Carleton), DCLC1056 (Carleton), DC LC1057 (Carleton), DCLC1062 (Carleton), DC LSF 9587 (Thales), DCLSF 9599 (Thales), DC 1W LINEAR (DRS), DC7062&196S (Raytheon), DC B602 (BEI), DCK527 (Ricor), DC UP 8497 (Thales), DC
Figure 17. Comparison of microminiature linear split Stirling
cryogenic coolers
Table 1. Comparison of microminiature linear split Stirling cryogenic coolers
In Table 1, the last three rows present, for comparison,
Ricor model K527 single-piston compressor in different
modifications. From Table 1, all the listed the dual-
piston compressors are essentially bulkier, heavier and
have shorter MTTF as compared with Ricor model
K527. The conservatively predicted MTTF in excess of
30,000 hours relies on experimental data obtained
during life testing of similar Ricor model K529
cryogenic cooler [12] which acquired 45,000
operational hours. It is important to remind the reader,
that the linear compressor of K529 cooler is driven by
the "moving coil" actuator and therefore comprises the
driving coil inside the Helium charged interior, flying
leads, feed-through and problematic heat sinking. The
K527 compressor is free of the above disadvantages and
has, therefore, a great potential for even longer MTTF.
The actual life testing is in the very beginning, the
authors will report on the outcomes.
Further, from Table 1, the vibration export produced by
vibration mounted K527 compressor is comparable with
this of its dual-piston rivals; adding 100gr tuned
dynamic absorber reduces the vibration export to typical
0.03N, which is of order of magnitude lower than this of
the listed rivals.
Figure 17 compares the power consumption of the
above coolers operating in the temperature control
(77K@23C) mode at different heat lifts, where the
marked points represent the performances of
"competitors" and bold solid line represents this of
Ricor model K527 cooler. It is important to notice that
Ricor model K527 cryogenic cooler has been designed