cryocooler analysis
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DC FLOW ANALYSIS OF PULSE TUBE CRYOCOOLER
Prepared by:
ROHIT H. PANSARA
(B.E. MECHANICAL)
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INDEX
SR NO. CONTENT PAGE NO.
Chapter 1 Introduction of cryogenics 1-11
1.1 Application of Cryogenic temperature 2
1.2 Limitation of vapour compression
Refrigeration system 2
1.3 Classification of cryocooler 4
1.3.1 Sterling cryocooler 5
1.3.2 Gifford Mc-Mahon cryocooler 7
1.3.3 pulse tube cryocooler 10
Chapter 2 Pulse tube cryocooler 12-18
2.1 Working mechanism of pulse tube
cryocooler 12
2.2 conditions of working 12
2.3 principle of pulse tube cryocooler 12
2.4 types of pulse tube cryocooler 14
2.4.1 basic pulse tube cryocooler(BPTC) 14
2.4.2 orifice pulse tube cryocooler(OPTC) 15
2.4.3 double inlet pulse tube cryocooler
(DIPTC) 17
2.4.4 inertance type pulse type cryocooler
(IPTC) 18
Chapter 3 Various loose in pulse tube cryocooler 19-23
3.1 Loss due to regenerative ineffectiveness 19
3.2 Temperature swing loss 20
3.3 Loss due to pressure drop in regenerator 21
3.4 Conduction loss 21
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3.5 Losses due to DC flow 22
Chapter 4 Modeling of DC flow losses 24-28
4.1 The assumption for developing model 25
4.2 Governing equation for calculation 27
SR NO. CONTENT PAGENO.
Chapter 5 Result and Discussion 29-34
5.1 Result for variation in pulse tube cold end Temperature 29
5.2 Result for different average pressure 31
5.3 Result for different frequency 32
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CHAPTER 1
INTRODUCTION OF CRYOGENICS
In a Greek language Cryogenics means Creation or Production by means of
cold.Cryogenics is a science dealing with low temperature. The low temperature is the
governing parameter in any cryogenics application. The temperature range of cryogenic is 0K to
123K. This range separates it from the temperature range generally used in refrigeration
engineering.
Cryogenics, the science of producing and maintaining low temperatures, had its beginning
in the later half of last century. It is concerned with design and development of cryocoolers that
are capable of producing and maintaining low temperature. It is a branch of low temperature
physics concerned with the effects of very low temperature was first investigated by Michael
Faraday who demonstrated that gases could be liquefied leading to the production of low-
temperature around 173 K.
The first cryogenic temperature system was primarily developed for the solidification of
carbon dioxide (CO2) and the liquefaction of a subsequent fractional distillation of gases such asair, O2, N2, H2 and He.
Oxygen (O2) was liquefied in 1877 by Coilletet and Pietet. H2 was liquefied in 1898 by
Dewar using Joule Thomson expansion gases. The liquid Oxygen boils at 90.2K and liquid
Hydrogen at 20.4K.The liquefaction of He (Helium) was accomplished in 1908 by
H.Kamerlingh in the famous cryogenic lab of university of LAIDEN. Initially, by evaporation
of liquid He (Helium) under high vacuum, the temperature as low as 1.1K was obtained. But by
making improvements in apparatus, a temperature of 0.7K was reached by the year 1928.
In term cryocooler is generally used for refrigerators of small size which are capable of
reaching temperature below 123K (-150 C).
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1.1. APPLICATIONS OF CRYOGENIC TEMPERATURE
(1) Cooling infrared sensors used on satellites and in missile guidance, night vision and rescue,atmospheric studies involving ozone hole and green house effect, low noise amplifiers.
(2) Commercial purpose such as cryopump for semiconductor fabrication, superconductor forcellular phone station, voltage standards, high-speed computer and process monitoring.
(3) Medical purpose like cooling super conducting magnets for MRI (magnetic Resonance andprocess monitoring). System, SQUIDs (Superconducting Quantum Infrared Device)
magnetometer for heart and brain studies, Croyogenic catheter and cryosurgery.
(4) Cryogenics Temperature also wildly used in Expansion Fitting, Cryobiology,Semen Preservation, Cryosurgery, Space Research, Computer Engineering, Cryogenic for
under Ground Power Lines, Miscellaneous Uses.
1.2. LIMITATION OF VAPOUR COMPRESSION REFRIGERATION SYSTEM
The solidification temperature of the refrigerants limits the use of VCR system for the
production of low temperature inherently. The following Table 1.1 shows the freezing
temperature of commonly used refrigerants in VCR.
Table 1.1: Freezing Temperature of Refrigerants Used in VCR
The refrigerants used must have a freezing temperature well below the required temperature
to be obtained. Thus the refrigerants R-113, NH3, CO2 and SO2 cannot be used for low
temperature refrigeration systems.
Refrigerants R-11 R-12 R-21 R-22 R-30 R-40 R-113R-717
(NH3)
R-744
(CO2)
R-764
(SO2)
Freezing
Temp (K) 162 215.5 138 113 176.4 175.5 238 195.2 216.3 197.4
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(a)The pressure required to be maintained in the evaporator for the required temperature is farbelow atmospheric pressure and it is difficult to maintain such high vacuum in the evaporator.
The pressure required to be maintained in the evaporator for maintaining 213K for different
refrigerants is given below in Table 1.2
REFRIGERANTSVACUUM PRESSURE
mm of Hg Bar
R-12 590 0.776
R-22 480 0.631
NH3 595 0.782
Table 1.2: Evaporator Pressures of Different Refrigerants
b) The specific volumes of the refrigerants at such a low temperature are extremely high and it isdifficult to operate the compressors efficiently under such low pressure when large volumes
of the gases are to be pumped.
c) With decrease in temperature, the compression ratio required may be as high as 200 and it stillincreases with decrease in evaporator temperature. The desired high compression ratio
reduces the volumetric efficiency of the compressors and also results in high temperature of
discharge gas leaving the compressor. The single stage reciprocating compressors are limited
to compression ratio of 12. As the volume displacements of the reciprocating compressors are
very low, they are not used at all for low temperature application.
d) The Horse Power (HP) required per ton of refrigeration increase in evaporating temperature.The performance is very poor at low temperature refrigeration system when single stage
compressor is used. The COP (Coefficient of Performance) of the VCR is very low for the
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production of low temperature. Below 173 K the COP of a single stage VCR system is lower
than cop of air refrigeration system in the same range of temperature.
e) Multistage compressor system can be used to overcome few difficulties but the majordrawback of multistage system is that the oil may not return to high-pressure compressor. Oil
may accumulate in one of the compressor, starving others. Suitable means as traps equalizing
float controls are required to prevent this.
1.3. CLASSIFICATION OF CRYOCOOLERS
Device which is use to produce cryogenics low temperature is called as cryocoolers.The term
cryocooler has generally been used for refrigerator of small and intermediate size, which is
capable to obtain and maintain temperature below 123K.
Crocoolers, invented in early 1960, are mainly classified in to two groups.
a) Recuperativeb) Regenerative
The Recuperative types utilize a continuous flow of the cryogen in the one direction, analogous
to a DC electrical system. The recuperative coolers use only recuperative heat exchanger and
operate with a steady flow of cryogen through the system the compressor operates with a fixed
inlet and outlet pressure. If the compress is reciprocating type, it must have inlet and outlet
valves to provide steady flow. The uses of valves in compressor needed for recuperative
cryocoolers limits the efficiency of the compression process about 50% and significantly limit
the overall efficiency of recuperative cryocooler.
In theRegenerativecycles the cryogen undergoes an oscillating pressure analogous to an
AC electrical system. The compressor or pressure oscillator for the regenerative cycles needs no
inlet or outlet valve. However, an oscillating pressure can be generated from a valve compressor
by using another set of valves to switch between the high and low pressure sides of the
compressor, as is done in the Gifford-McMahon cryocooler. The regenerator has only one flow
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channel and the heat is stored for a half-cycle in the regenerator matrix, which must have a high
heat capacity (>98%).
Expansion type cryocoolers are mainly of three types:
1) Stirling Cryocooler2) Gifford-McMahon Cryocooler3) Pulse tube cryocooler1.3.1 Stirling Cryocooler
The cycle consists of four stages as shown in Figure 1. The Figure 2 shows Pressure vs.
Volume diagram and temperature profile respectively. The sequence of operations for the Stirling
cryocooler is as follows:
Phase 1:
During this process the gas is compressed isothermally. During the compression pressure is
increase and as the process is isothermal the volume is decreased. For making the process
isothermal the heat generated, as the result of compression is removed by heat exchanger at
ambient temperature.
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Phase 2:
During this process the volume of fluid is constant. As fluid passes through the regenerator it
been cooled (because the effect of the cold fluid, when it is passed through regenerator during 4th
process). Here also as the temperature decreases, by the constant volume, the pressure is also
decreases.
Phase 3:
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During this process as the displacer is moving part it work freely and displace towards left and
fluid get expand. As the fluid is expanded the pressure is decreasing slightly and the volume is
increasing. Here we get expansion effects of fluid. As whatever the cooling effects produced is
used for making the evaporator at the required temperature, the process is been isothermal
expansion. At point D we get maximum cooling effect.
Phase 4:
During this process, the displacer forced the fluid towards right. The fluid gets hot as it passes
through regenerator from left to right. As the volume is been constant the pressure is increasing.
Thus, by repetition of these all four phases from 1 to 4 we get the useful and continuous cooling
at point D.
Stirling cycle cryocooler operate on a closed thermodynamic cycle with two external heat
exchange processes and two internal constant volume regenerative processes.
It is well known that an ideal Stirling cycle has the same efficiency as that of the Carnot cycle and
thus the Stirling system is potentially very efficient. The actual refrigeration available to cool
thermal load is that available in an ideal case less the thermal and pneumatic losses in the system.
The practical realization of the Stirling cycle has only become possible with the development of
efficient regenerator.
1.3.2. Gifford-McMahon Cryocooler:
Because of the pressure oscillates everywhere within the Stirling cryocooler, excess void
volumes must be minimized to maintain a large pressure amplitude for a given swept volume of
the piston. Thus oil removal equipment cannot be tolerated which means that the moving piston
and displacer must be oil-free. But long lifetime then becomes difficult to achieve.
In the mid of 1960s Gifford and McMahon showed that the pressure oscillation for
cryocoolers could be generated by the use of a Distribution Valve that switches between high and
low pressure sources.
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The G-M cryocooler has the same low temperature parts as the Stirling cryocooler. The
irreversible expansion through the valves significantly reduces the efficiency of the process, but
the advantage of this approach is that it allows for an oil-lubricated compressor with oil-removal
equipment on the high side to supply the high and low pressure sources. Oil-lubricated
compressors were readily available at low cost from the air-conditioning industry by the mid
1960s with continuous operation.
To maintain a 1 to 3 years lifetime for the PTFE based seals on the displacer and the
Distribution Valve, G-M used low speeds of 1 Hz to 2 Hz for those two components in the cold
head. The cold head could be placed quite some distance from the compressor and connected by
flexible lines for the high and low-pressure gas.
The G-M cryocoolers are now manufactured at a rate of about 20,000 per year for use in
cryo-pumps. Schematic of the Gifford-McMahon cryocooler is shown inFigure1.5
This system consists of a compressor, a cylinder closed at both ends, a displacer within the
cylinder and a regenerator. Here no work is transferred from the system during the expansion
process. The displacer serves the purpose of moving the gas from one expansion space to another
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and would do zero work in the ideal case of zero pressure drops in the regenerator. The
temperature vs. entropy diagram for G-M cryocooler is shown inFigure 1.6.
The sequence of operations for the Gifford-McMahon Cryocooler is as follows:
Process 1-2:
With the displacer at the bottom of the cylinder, the inlet valve is opened and the pressure within
the upper expansion space is increased from lower pressure P1 to a higher pressure P2. The
volume of the lower expansion space is practically zero during this process because the displacer
is at its lowest position.
Process 2-3:
During this the inlet valve still open and the exhaust valve closed, the displacer is moved to the
top of the cylinder. This action moves the gas that was originally in the upper expansion space
down through the regenerator to the lower expansion space. Because the gas is cooled as it passes
through the regenerator, it will decrease in volume so that gas will be drawn in through the inlet
valve during this process to maintain a constant pressure within the system.
Process 3-4:
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With the displacer at the top of the cylinder, the inlet valve is closed and the exhaust valve is
opened. Thus by redirecting the 3-way valves and allowing the gas within the lower expansion
space for expand to the initial pressure P i. During this the gas passes through the evaporator and
gives the cooling.
Process 4-5:
The low temperature gas is forced out of the lower expansion space by moving the displacer
downward to the bottom of the cylinder. This cold gas flows through a heat exchanger in which
heat is transferred to the gas from low temperature sources.
Process 5-1:
The gas flows from the heat exchanger through the regenerator, in which the gas is warmed back
to near ambient temperature.Thus the cycle is repeated in this way and we get the cooling effect.
1.3.3. Pulse tube cryocooler:
In Stirling Cryocoolers, the pressure of moving part in the cold region gives rise to vibration,
friction, wears and tears problems, which are its main drawbacks. A major advantage of the G-M
system is the ease with which several units may be multistage to achieve temperature as low as 15
K to 20 K. The Pulse tube cryocooler develops by Gifford and Longworth derives cooling from
the compression and expansion of gas. As the Pulse Tube contains no moving parts in the cold
region, it has greater reliability and lifetime than the former ones. The only obstacle to its wide
applications is relatively low refrigeration performance as compared to other types. The minimum
temperature attained by one stage was much higher than 79 K so 2 or 3 stages are necessary to
reach very low temperature.
Pulse tube refrigeration is based on the cyclic process such that a gas column with cold and
warm end temperatures, Tcand Tw, respectively, is compressed, displaced towards the warm end,
expanded, and re-displaced towards the cold end.
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The process is realized by feeding adequate gas flows to both ends of the tube. Those flow
rates must be different in size and in phases. The various types of pulse tube refrigerators differ
mainly by the performance of the phase shifter which can by realized by use of passive or active
elements. Using those flow rates as basic quantities, alternative types of operational diagrams for
describing the differences and the common features of various types of pulse tube refrigerators,
are derived. They provide simple means for the basic layout and for its optimization. Those
results will be compared with more detailed numeric simulations and also with experiments from
the literature. The single stage VCR system for the different refrigerants is limited to an
evaporator temperature of 234 K.
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CHAPTER 2
PULSE TUBE CRYOCOOLER
2.1 WORKING MECHANISM OF PULSE TUBE CRYOCOOLER
Pulse Tube Cryocooler was built by Gifford and Longworth [1] in 1960s. It has no moving
part in low temperature region and is inherently simple and reliable, with low vibration and long
lifetime. Mikulin et al [2] invented Orifice Pulse Tube Cryocooler. He has reached 3.6K with 3-
stage Orifice Pulse Tube Cryocooler. It uses modest pressure and pressure ratio. It has low
refrigeration rate per unit mass flow. In 1989, Shaowei introduced the double inlet method. They
obtained the lowest temperature of 132k using Double Pulse Tube Cryocooler while it was 175k
obtained from Orifice Pulse Tube under the same operating conditions. S.Zhu built the latest
development in the field of Pulse Tube Cryocooler. It has higher efficiency than the previous
types.
2.2 CONDITIONS FOR WORKING
There are three conditions that are necessary for the Pulse Tube Cryocooler to work:
1. The gas must reach the low temperature point without carrying a lot of heat (as measured bythe enthalpy flow in the regenerator).
2. The amplitude of the gas flow and pressure oscillation in the Pulse Tube section must belarge enough to carry away (by enthalpy flow) the heat applied to the cold heat exchanger.
3. The phase relationship between the pressure the gas flow in the Pulse Tube section must beappropriate to carry heat away from the cold point (by enthalpy flow from cold end to the hot
end).
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2.3 PRINCIPLE OF PULSE TUBE CRYOCOOLER
When a gas at room temperature is admitted to one end of tube (shown in Figure 2.1),
closed at far end, so that pressure in tube is raised, there will be a tendency for a temperature
gradient to be established within part of the tube.
F igure 2.1: Pr inciple of Pulse Tube Cryocooler
This gradient will be most pronounced if the gas enters with plug flow, without turbulent
mixing in tube and with minimal heat transfer to the wall. Then all gas initially within the tube
will undergo isentropic compression and its temperature T can be given by relationship:
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This gas is displaced towards the closed end of the tube. Between, gas at hot end regionthat is at higher temperature due to isentropic compression and the gas at the open end of the
tube, which is still at T0, a temperature gradient will be established in the tube. If heat is rejected
in the region of closed end (hot end) of the tube to restore the gas temperature to near To and the
pressure suddenly released through the opened end of the tube, the gas will be expanded by a
near isentropic process back to its original pressure and will reoccupy most of the tube. This gas
will be at the temperature below T0, and there for will be capable of performing refrigeration.
In the field of cryogenics Pulse Tube Cryocooler is attractive as a high reliability and low
vibration cryocooler because there is no moving part at the cold section. Also due to improved
thermodynamic efficiency the Pulse Tube Cryocoolers are now getting more importance.
2.4 TYPES OF PULSE TUBE CRYOCOOLER
2.4.1 Basic Pulse Tube Cryocooler (BPTC)
The basics Pulse Tube Cryocooler was originally developed by Gifford and Longsworth
[1]. It consists of compressor, flow reversing valve, regenerator and an open tube as shown in
Figure 2.2. The flow-reversing valve is located after the compressor and controls the pressure in
the Pulse Tube.
Operation of the Pulse Tube Cryocooler begins by opening an inlet valve, which permits high-
pressure gas to flow through the regenerator, where transferring energy to the regenerator cools
it. The gas then enters open end of the Pulse Tube where the first heat exchanger is located. The
heat exchanger raises the temperature of the gas at constant pressure. This partially heated gas
behaves like a gas piston, adiabatically compressing the gas already in the tube. This
compression results in a temperature rise of the gas inside the tube and forces the gas to the
second heat exchanger.
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In the second heat exchanger, to maintain a constant temperature the gas is cooled by exchanging
heat with cooling water. Once the pressure in the reaches a specified level, the inlet valve closes
and the exhaust valve opens, allowing expansion of the gas inside the tube accompanied by a
cooling effect. The temperature of the gas leaving the Pulse Tube is lowers that the temperature
at which it entered, creating the refrigeration effect. The expanding gas flows back through the
exit valve.
Once the original low-pressure level in the pulse tube is reached, the exit valve close, the gas is
recompressed polytropically and the process begins again. The lower half offigure 2.1 depicts a
temperature versus position graph for the entire refrigeration cycle. By cycling the gas back and
forth many times per minute, large temperature gradient can be achieved and maintain.
F igure2.2: Basic Pul se Tube Cryocooler (BPTC)
2.4.2 Orifice Pulse Tube Cryocooler (OPTC)
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The minimum temperature attained by BPTC was limited to 100K and to go below this
temperature it requires multistage. This barrier has been overcome by the important
breakthrough made during the last few years.
In 1984, Mikulin et al [2] installed an orifice and gas reservoir at the top of the Pulse Tube to
allow some gas to pass in to and out of large reservoir volume. This type of Cryocooler called an
Orifice Pulse Tube Cryocooler (OPTC), as shown in figure 2.3. It is capable of reaching much
lower temperature than the basic type. Mikulin et al [2] have attained low temperature of 79K.
F igure 2.3:Ori f ice Pulse Tube Cryocooler (OPTC)
Advantages of OPTC over BPTC are as follows:
a) Only one moving part and that is also at room temperature It uses modest pressure andpressure ratios. It is possible to achieve works on ideal gas, which implies one fluid for all
temperature.
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b) Large orifice will not collect impurities at high temperature part of cycle.c) It has good intrinsic efficiency.d) It can be operate with several stages from the same pressure wave generator.
In OPTC, the available phase angle of gas displacement at the hot end of Pulse Tube
corresponding to piston motion is restricted between 00
and 900. Thus OPTC cannot achieve
optimum phase angle, which is between 900
and 1800. The other disadvantage is the low
refrigeration rate per unit mass flow, which means that the better regenerators are required.
2.4.3 Double Inlet Pulse Tube Cryocooler (DIPTC)
S. Zhu et al [3] introduced the double inlet method, which further improved the
performance.
It was found that due to another inlet at the hot end of the P.T., mass flow from cold end to hot
end could be reduced. In other words, refrigeration power per unit mass flow rate through the
regenerator will be increased. This type of Pulse Tube cryocooler as shown inFigure 2.4 can be
called as DIPTC. The lowest temperature was 132K with DIPTC and 175K using OPTC under
same operating conditions.
The experiment also showed that the rate of temperature drop in DIPTC was greater than OPTC,
which means increased gross refrigeration.
The main contribution of double inlet Pulse Tube is to adjust the phase shift between the pressure
wave and mass flow in the Pulse Tube and to increase their amplitude. It was found that the
improvement achieved with DIPTC could be explained by their capability to reach phase angle
beyond 900.
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F igure 2.4: Double Inlet Pulse Tube Cryocooler (DI PTC)
2.5.4. Inertance Type Pulse Tube Cryocooler (IPTC)
The earliest use of an IPTR appears to be that reported by Kanao. They measured performance as
a function of the diameter and length of the tube, as well as of frequency. They concluded that neither
the single orifice nor the double inlet configuration provided better performance than the inertance
configuration. The first detailed analysis of the IPTR was reported by Zhu et al [3]. They called the
inertance tube the "long neck tube", and carried out computer calculations providing the performance as
a function of the diameter and length of the tube. The calculations were verified by an experiment in
which a long tube was connected directly between the reservoir and the compressor volume.
The inertance tube is placed between the pulse tube proper and the reservoir. For proper values
of its length and diameter, this arrangement conceivably results in improved performance, when
compared with other arrangements. This is because the inertance tube offers a good deal of flexibility,
potentially resulting in oscillating velocity and pressure with a phase relationship similar to that in
Stirling refrigerator. Present work comprises of design, development and testing of the inertance type
of pulse tube cryocooler.
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Figure 2.5: I nertance Type Pulse Tube Cryocooler (IPTC)
CHAPTER 3
VARIOUS LOSSES IN PULSE TUBE CRYOCOOLER
It can be revealed from the literature that the pulse tube cryocooler operates on a cycle
similar to Stirling cycle. Refrigeration capacity of a cryocoolers decreases due to the losses like
regenerator ineffectiveness, shuttle heat conduction, temperature swing, pumping action,
instantaneous pressure drop, heat conduction through various solid parts etc. Dead volumes also
give rise to losses and should be reduced to minimum. If the effects of all individual losses
identified are combined, as they are in the real situation, then the net refrigerating power is
substantially reduced from that pertaining to the ideal case. The loss analysis of a cryocooler is
very important to estimate the efficiency and realistic performance.
3.1 Loss Due to Regenerator Ineffectiveness:
In pulse tube cryocooler the amount of gas that passes through the regenerator is quite
large and consequently the load on regenerator is also large. Hence, the regenerator is a critical
component that influences the performance of pulse tube cryocooler and the regenerator
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efficiency is critical to the overall performance. The regenerator performance varies with
different mesh structures used and also with properties of mesh matrix material.
The incoming gas is cooled to a slightly higher temperature than to which it can, in the
regenerator due to its ineffectiveness and thereby causing loss of refrigeration power. As
suggested by Miyabe [6] this loss can be calculated as under:
(13)
The fractional time is the effective fraction of total cycle time during which the steady
flow of gas enters into the pulse tube through regenerator. If the effect of pressure change duringthe gas flow through the regenerator is considered than the above equation can be rewritten as
{ } .(14)
To calculate this loss on a cyclic basis, the effectiveness is to be calculated for each
fractional time in the regenerator. The loss due to ineffectiveness of the regenerator for every
interval is to be calculated and summed up to cumulative value of this loss.
3.2 Temperature Swing Loss:Temperature swing loss accounts for the temperature changes in the matrix of the
regenerator during the cycle. It is the heat taken up by the matrix due to its finite capacity. The
drop in the temperature of regenerator matrix all along the length due to the single flow of the
gas should be calculated as described by Martini [8].
Temperature swing of the regenerator matrix material can be obtained as;
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.(15)
The temperature swing loss is calculated when the gas moves through the regenerator during
pressurization process during the cycle and therefore, is equal to
(16)
3.3 Loss Due To Pressure Drop In The Regenerator:
Due to pressure drop in the regenerator and other parts the actual pressure in the pulse
tube will be lower than the supply pressure. During the expansion process the gas cant be
expanded in the pulse tube to the lowest possible pressure due the same reason. This results in
reduction of p-v area of gas III and hence reduction of the refrigeration power. It is dependent of
flow acceleration and core friction. The flow acceleration term can be ignored for full cycle. To
estimate this loss, first of all the pressure drop is to be estimated based on viscosity of gas,
density of gas, mass velocity, Reynolds number and friction factor as under;
.(17)
To calculate this loss, the refrigerating effect with this pressure drop is to be subtracted fromthat obtained without considering pressure drop i.e. the gross refrigeration power.
3.4 Conduction Losses:
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This loss is basically due to heat conduction from high temperature region to low
temperature region. It occurs through the pulse tube, regenerator tube liner and regenerator
matrix. These losses also reduce the net refrigeration power and can be calculated from the basic
heat transfer equations in the cyclic manner
(i) Conduction through Pulse tube
..(18)
(ii) Conduction through Regenerator Liner
..(19)
(iii) Conduction through Matrix
..(20)
The conductivity of matrix (kMatrix) can be obtained as;
..(21)
The factorKX can be obtained as;
..(22)
Net refrigeration power is calculated by subtracting all the losses from the gross
refrigeration power.
3.5 Losses due to dc flow
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Adding second orifice valve between the hot end of pulse tube and the compressor, according
to the opening of the orifice valve dc flow is established in the pulse tube. When the mass flow is
counter clockwise from cold end of regenerator to the cold end heat exchanger is called
positive dc flow and mass flow is in the clockwise cold end heat exchanger to the regenerator
cold end is called negative dc. Complete explanation of the DC flow is in the chapter 4.
CHAPTER-4
MODELLING OF DC FLOW LOSSES
Adding a second orifice valve between the hot end of the pulse tube and the compressor
significantly improves the performance by decreasing the mass flow rate through the regenerator
that does not contribute to the actual cooling power generation. However, this new configuration
also introduces a possibility for unbalanced, unidirectional flow, analogous to direct current in an
electrical circuit. Figure 4.1 shows a schematic diagram of a G-M type double-inlet pulse tube
refrigerator. During the compression process, high pressure gas flows out of the compressor and
is divided into two flow streams one to the hot end of the regenerator, and the other to the hot
heat exchanger through the orifice valve. Flow resistances of the regenerator and the double-inlet
orifice valve determine the ratio of the mass flow rates into the system. During the expansion
process, mass flows from the regenerator and the hot heat exchanger back to the compressor.
However, the flow resistance for gas that returns to the compressor can be different from that for
the gas coming out of the compressor. Typically orifice valves have directional characteristics,
i.e. the mass flow rate at the same pressure ratio may be different when the orifice valve is
installed in the reverse direction. Also, in the regenerator, the pressure drop that is represented as
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flow resistance is a function of the pressure difference between the regenerator ends, as well as
the temperature, density and other fluid dynamic values such as velocity. The pressure drop can
be different for the compression and expansion process. This potential imbalance in flow
resistance can generate a unidirectional net mass flow rate in a pulse tube system. The net mass
flow is zero for an ideal balance of flow resistances. However, in actual conditions, the net mass
flow can be counterclockwise (i.e., a positive DC flow through the cold heat exchanger) or
clockwise (i.e., a negative DC flow through the cold heat exchanger) in figure 4.1 If the system
has a positive DC flow, more cold gas flows from the cold end of the regenerator to the cold end
of the pulse tube with the result that the gas temperature can be lower during the expansion
process. In other words, the system ideally produces more cooling power. However, a positive
DC flow also increases the mass flow rate through the regenerator and the pressure drop in the
regenerator. The mass flow rate in the regenerator is also unbalanced. On the other hand, a
negative DC flow increases the heat load to the cold end of the pulse tube. As the mass flow
from the hot end to the cold end of the pulse tube is increased, higher temperature gas may reach
the cold end of the pulse tube and this additional mass flow decreases the cooling power of the
system. As mentioned above, DC flow causes several different effects and its impact on the
system performance is not obvious. In the G-M type pulse tube refrigerator, valves (V1~V
4)
perform the function of the double-inlet orifice valve. Therefore the system has the possibility
for DC flow. The numerical cycle simulation described above can evaluate the direction andamount of DC flow.
In present work DC flow in Pulse tube cryocoolers is modeled using MATLAB software.
Effect of frequency, cold end temperature, orifice and double inlet opening on DC flow and
hence on performance of the system can be studied using the present model.
The model is explained in following section. The assumption made to develop the model
is listed below.
4.1 The assumption for developing model:
1. Helium, the working gas, behaves as a perfect gas (an ideal gas with constant specificheat).
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2. Flow in the system is one dimensional, so that there is no velocity component normalto the walls in each component.
3. The effectiveness of the regenerator is unity and the regenerator wall temperaturedistribution is constant.
4. The pressure drops in the regenerator and connection tubings are neglected. Thepressure in the regenerator, pulse tube and heat exchangers are the same at any time.
5. In the cold and hot heat exchangers, the gas temperature is the same as that of thewall temperature of the heat exchanger, which is constant, i.e., heat transfer is perfect
in the heat exchanger.
6. In the pulse tube, the flow is adiabatic
7. Flow through the orifice valves is adiabatic.
8. The temperature of the reservoir is isothermal.
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Figure 4.1 G-M type pulse tube cryocooler
4.2 Governing equation use for calculation.
For calculation of mass flow through orifice 3, 4 and 5 we are using nozzle
equation because there is needle valve which outlet area is not equal inlet area but it is variable.
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[
(
)
]
.. (4.1)
The value of, and are calculated using above equation of the orifice valve.Now these values of the mass flow are put in the equation of change in pressure with respect totime dP/dt as below.
.. (4.2)
In above equation and are primary flow and it is negligible for calculation ofDC losses so it not use in calculation purpose. Now calculating the mass flow in the regenerator
respective equation for mass conservation in regenerator, For mass conservation we are dividing
regenerator in to the 5 discrete part because for different part there is different temperature of the
part as shown in the figure 4.1.
.. (4.3)
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...... (4.4)
...... (4.5)
.... (4.6)
.... (4.7)
And finally we are putting the value of the mr5 in given below equation and we get the
value of losses due to DC flow.
*h .... (4.8)Where h=Enthalpy of helium at that temperature
...... (4.9)
CHAPTER-5
RESULT AND DISCCUSION
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5.1 Results for variation in pulse tube cold end temperature
The present model is used to understand the DC flow losses at various operating
parameters. As discussed in earlier section DC flow is harmful but inevitable in pulse tube
crycoolers. DC flow is affecting the overall performance of the G-M type pulse tube cryocoolers.
Temperature 40 0.9017 7.2278 7.4276 4.0111
50 1.3235 7.6496 7.0058 4.7101
60 1.8076 8.1338 6.5216 5.3609
70 2.3497 8.6759 5.9795 5.9730
80 2.9464 9.2725 5.3829 6.5534
Table 5.1 Effect of cold end temperature on cooling power
Graph 5.1
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Graph 5.2
Effect of DC flow loss & other losses at different temperature are predicted from model. The
result of DC flow loss at cold end temperature is shown in graph 5.1 & net refrigeration power at
cold end temperature is shown in graph 5.2.As shown in graph 5.1 cold end temperature increase
heat loss due to the DC flow is increase & according to the graph 5.2 as cold end temperature
increase net refrigeration power is decrease.
Graph 5.3
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Graph 5.4
The results are tabulated in table 5.1 regenrator mass flow at various temperature are
calculated and shown in graph 5.3 & effect of regenrator mass flow rate on DC flow losses is
shown in graph 5.4.In graph 5.3 shows that as cold end temperature increases mass flow through
the regenrator increases, and graph 5.4 shows that as mass flow increases DC flow heat loss also
increase.
5.2 Results for different average pressure
Effect of avarage pressure is studied and results are shown in graph 5.5 & 5.6 for DC loss
and refrigeration power respectivly model predicts that lower avarage pressure results in lower
losses and higher refrigeration power. The results are tabulated in table 5.2.
Pressure 13 2.8008 9.1269 5.5285 6.2295
14 2.9464 9.2725 5.3829 6.5534
15 3.0858 9.4119 5.2435 6.8634
16 3.2204 9.5465 5.1089 7.1628
17 3.3510 9.6772 4.9783 7.4534
Table 5.2 Effect of average pressure on cooling power
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Graph 5.5
Graph 5.6
As shown in graph 5.5 which is Vs average pressure which is indicated that as averagepressure is increase DC flow loss is also increse, and in graph 5.6 indicate that as average
pressure increase net refrigeration power is decreases.
5.3 Resuls for different frequances
Effect on DC flow losses and net refrigeration power at different frequency are
predicated from the model. The results are tabulated in table 5.3.The resuls of DC losses at
different frequency shown in graph 5.7 and net refrigeration power at different frequency as
shown in graph 5.8.
Frequency 1 4.8562 11.1823 3.4731 10.8012
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2 4.7176 11.0437 3.6117 10.4928
3 4.6900 11.0161 3.6393 10.4315
4 4.6802 11.0063 3.6491 10.4097
5 4.6756 11.0017 3.6537 10.3995
Table 5.3 Effect of frequancy on cooling power
Graph 5.7
Graph 5.8
In graph 5.7 shows frequency Vs DC loss graph as frequency increases DC losses aredecreases and as shown in graph 5.8 shows graph of frequency Vs Qnet as frequency increases
net refrigeration power also increases.
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