Small 4 K cryocoolers for the cooling of low temperature superconducting (LTS) electronic systems are necessary for broader commercial, military, or space applications of such devices. Typically these cryocoolers have been either Gifford-McMahon (GM) cryocoolers or GM-type pulse tube cryocoolers that operate at frequencies of about 1 Hz. The efficiency of these cryocoolers ranges from 0.5 to 1.0% of Carnot, whereas 80 K cryocoolers often achieve efficiencies of about 15% of Carnot. The low efficiency of 4 K cryocoolers causes these cryocoolers to have large, noisy compressors with high input powers. The low operating frequency of the GM and GM-type pulse tubes also leads to large temperature oscillations at the cold end at the operating frequency of the cryocooler. The amplitude of the temperature oscillation decreases inversely with the cryocooler operating frequency.
Higher operating frequencies allow the use of Stirling cryocoolers or Stirling-type pulse tube cryocoolers, which have much higher efficiencies in converting electrical power to PV power. These frequencies are typically in the range of 30 to 60 Hz. The linear Stirling-type compressors (pressure oscillators) often use flexure bearings that eliminate rubbing contact and operate almost silently. However, these higher frequencies generally lead to greater losses in a 4 K regenerator unless the operating parameters are near optimum conditions. Recent regenerator modeling efforts have shown that the phase angle between flow and pressure at the cold end has a strong effect on the 4 K regenerator second law efficiency. In order to achieve an optimum phase of about −30° (flow lagging pressure) at the cold end, a phase of about −60° at the pulse tube warm end is required. Inertance tubes are typically used for phase shifting, but with the small refrigeration powers of interest for electronics cooling, phase shifts of only a few degrees are possible at 30 Hz, even with the inertance tube and reservoir at a low temperature of 30 K. A double inlet configuration with a secondary orifice between the regenerator and pulse tube warm ends can only provide a practical phase shift of about 30° before the lost work in the secondary orifice greatly reduces the overall efficiency. The double inlet approach also introduces the possibility of DC flow, which can reduce the efficiency.
Larger phase shifts with small acoustic powers can be achieved by the use of a warm expander or warm displacer at the warm end of the pulse tube. For single stage pulse tube cryocoolers or for two-stage pulse tube cryocoolers operating at about 1 Hz (GM-type), the warm end of the pulse tube operates at ambient temperature. A 4 K pulse tube may need to have the warm end at 30 K or lower to keep the efficiency of the pulse tube component high, at least for a high frequency of about 30 Hz. It would then be necessary to develop an expander that can operate at about 30 K.
In view of the foregoing, it would be desirable to provide a pulse tube refrigeration system having a room temperature phase shifter or expander.
The difficulties and drawbacks associated with previously known systems are addressed in the present invention systems and methods.
In one aspect, the present invention provides a pulse tube refrigeration system comprising a compressor, a regenerator in fluid communication with the compressor, and a pulse tube defining a cold end and a warm end. The regenerator is in fluid communication with the cold end of the pulse tube. The system also comprises a secondary component selected from (i) a secondary regenerator and (ii) a secondary pulse tube, wherein the secondary component is in fluid communication with the warm end of the pulse tube. And, the system comprises an expander in fluid communication with the warm end of the secondary component.
In another aspect, the present invention provides a pulse tube cooling system comprising at least one of (i) a cryocooler and (ii) a compressor, and a pulse tube in fluid communication with the at least one of (i) the cryocooler and (ii) the compressor. The pulse tube has a cold end and a warm end. The system also comprises an ambient temperature phase shifter component. And, the system comprises a secondary component selected from (i) a secondary regenerator and (ii) a secondary pulse tube. The secondary component is in fluid communication with, and disposed between, the warm end of the pulse tube and the phase shifter component at some higher temperature (nominally at ambient temperature).
In still another aspect, the invention provides a method for using a phase shifter at ambient temperature in a multistage pulse tube cooling system. The pulse tube cooling system includes a compressor, a regenerator, a pulse tube having a cold end and a warm end at sub-ambient temperature, and the phase shifter at ambient temperature. The method comprises providing a secondary component selected from (i) a secondary regenerator and (ii) a secondary pulse tube. The method also comprises establishing fluid communication between the secondary component and the warm end of the pulse tube at sub-ambient temperature. Upon operation of the cooling system, the phase shifter is at ambient temperature.
As will be realized, the invention is capable of other and different embodiments and its several details are capable of modifications in various respects, all without departing from the invention. Accordingly, the drawings and description are to be regarded as illustrative and not restrictive.
a)-2(c) are schematic illustrations of three known phase shifting methods for pulse tube cryocoolers.
a)-4(b) are schematic illustrations of known mechanical phase shift mechanisms used in regenerative cryocoolers.
a)-5(b) are schematic illustrations of two preferred embodiment cooling systems in accordance with the present invention.
The present invention is based, at least in part, upon a discovery that by incorporating a secondary regenerator or a secondary pulse tube at a warm end (but still below room temperature) of a pulse tube, a phase shifter or expander in a pulse tube cooling system can be operated at room temperature. Furthermore, it has been discovered that a wide array of commercially available pressure oscillators can be used for the room temperature phase shifter or expander. These and other aspects are described in greater detail herein.
Generally, multistage pulse tube cryocoolers require separate phase shifters for each stage. For sufficiently high frequency and acoustic power, an inertance tube is typically used for such phase shifting. For Stirling-type multistage pulse tube cryocoolers, the warm end of the coldest pulse tube is often heat sunk to the cold end of a warmer stage rather than at room temperature to improve the figure of merit for the pulse tube and/or to achieve a larger phase shift with a cold inertance tube. The use of a secondary pulse tube or regenerator between the main pulse tube and a phase shifter allows the phase shifter to operate at room temperature where space is more readily available. The use of a secondary pulse tube or regenerator also allows for the use of commercially available pressure oscillators as expanders. The secondary regenerator amplifies the acoustic power, so that a room temperature inertance tube may perform as well as a cold one. A secondary pulse tube transfers acoustic power to room temperature without amplification, so a rather small warm expander or displacer can provide the optimum phase shift even in a low-power cryocooler. As described herein, the behavior of these secondary pulse tubes and regenerators was investigated to determine the optimum geometry and the optimum characteristics for the expander.
In the descriptions herein, references are repeatedly made to a “cold end” of a component or region in a cooling system. Typically, this is the location at which the lowest temperatures are achieved. For many of the systems described herein, the cold end is the end of a pulse tube used in the system and which may reach temperatures as low as about 4 K. It will be understood that in no way is the present invention limited to such temperatures nor to cooling systems providing such temperatures. Instead, it will be understood that the references to 4 K are merely representative. Furthermore, it will be appreciated that various references to 30 K are not limiting. These temperatures are merely noted to provide a better understanding of the subject matter and invention.
The coefficient of performance (COP) of a regenerator is given by formula (1):
where {dot over (Q)}net is the net refrigeration power at the cold end, and <P{dot over (V)}>h is the time-averaged acoustic or PV power at the hot end of the regenerator. For an ideal gas and a perfect regenerator, the ideal COP for a regenerator is given by (Tc/Th), where the reversible expansion work at the cold end is assumed to not be fed back to the hot end of the regenerator. Thus, the thermodynamic second law efficiency of the regenerator is given by formula (2):
η=(Th/Tc)COP. (2)
Calculations of the COP and efficiency of 4 K regenerators at 30 Hz were carried out using a publically available software package designated as REGEN3.3 and available from the present assignee. The losses considered in calculating the COP were the real gas effects, the regenerator ineffectiveness, and conduction in the matrix. No pulse tube losses were considered, but in practice they are believed to be approximately 20% to 30% of the gross refrigeration power available at the cold end. It was determined that the phase angle φc between the flow and pressure at the cold end has a strong effect on the regenerator efficiency, as shown in
a)-2(c) illustrate schematics of three common phase shift mechanisms used for pulse tube cryocoolers. The orifice, shown in
The second configuration in
If the pulse tube warm end is at 30 K, then the double inlet normally must be at that temperature. The use of two needle valves at 30 K greatly complicates the operation and/or control of the system. The secondary orifice could be located at room temperature if a small secondary regenerator is placed between it and the pulse tube warm end at 30 K. The other side of the secondary orifice would be connected to the transfer line at room temperature between the compressor and the aftercooler. As far as is known, because a secondary regenerator has never been utilized before, such a configuration was investigated and modeled as discussed herein, in an effort to optimize the system. The use of a secondary regenerator is not an ideal solution, because the added gas volume reduces the possible phase shift. The flow impedance of the secondary regenerator could be made high enough to provide most of the impedance, and the room temperature needle valves would be used only to provide a small amount of adjustment to the overall impedance.
Often the primary orifice in a double inlet configuration is replaced with an inertance tube, even when it provides only a few degrees of phase shift. These few degrees add to the phase shift that the double inlet can provide as compared with the primary orifice being a simple orifice.
The inertance tube, as shown schematically in
With the second configuration shown in
Ideally, for certain applications, it would be desirable to place an expander at the warm end of the 4 K pulse tube. The expansion work could be used to drive a linear alternator whose electrical output power is either fed to room temperature to be dissipated as heat or is used to provide electrical power to drive low power superconducting electronics at 4 K. The later strategy eliminates the conduction loss in electrical leads at the higher stages. The low electrical resistivity of copper at 30 K also means that the Joule heating in the alternator would be very small compared to the recovered mechanical power. Such an expander and alternator could be in the form of a commercial pressure oscillator run in reverse to provide power instead of supplying the pressure oscillator with power. Unfortunately, most commercial pressure oscillators are not designed to operate at cryogenic temperatures. A specially designed expander would need to be developed for use at about 30 K to use it at the warm end of a 4 K pulse tube. A second, and much more convenient option, is to use a commercial pressure oscillator as an expander at room temperature, but couple the pressure oscillator to the 30 K pulse tube warm end by a secondary regenerator or a secondary pulse tube. A commercial pressure oscillator can be controlled electrically to provide any phase shift within the bounds of its swept volume and maximum current. A linear motor can generate electric power from the recovered PV power, or electric power input may be required if the expander is operating far from resonance and the Joule heating is larger than the generated power.
A fundamental difference between the secondary regenerator and the secondary pulse tube is that the regenerator behaves nearly like an isothermal element, which amplifies acoustic power proportional to the temperature. Thus, the volume flow rate also increases with temperature and a larger expander is required at room temperature compared with one that might operate at 30 K. The secondary pulse tube operates nearly like an adiabatic element, which transmits acoustic power from cold to hot with no amplification. Therefore, a secondary pulse tube is preferred, because a smaller swept volume is required of the expander.
Specifically,
Specifically,
The software REGEN3.3 was used to model both the secondary regenerator and the secondary pulse tube. The software uses a finite difference technique to evaluate the four conservation equations in a regenerator. The software was designed to model a normal cryocooler regenerator in which the acoustic power flow is from the hot end to the cold end. Details as to this software are provided in Radebaugh, R., Huang, Y., O'Gallagher, A., and Gary, J., “Optimization Calculations for a 30 Hz 4 K Regenerator with Helium-3 Working Fluid,” Adv. Cryogenic Engineering, Vol 55, Amer. Inst. of Physics, New York, 2010, pp. 1581-1592. It was determined that the software is also useful in modeling regenerators with the power flow in the opposite direction. The only change required in the input conditions is to add 180° to the phase of the cold end mass flow with respect to the pressure. That change causes the acoustic power flow to travel from the cold to the hot end of the regenerator.
The software has not been used in the past to model pulse tubes, because the software was not designed for that task. However, with the ability to have acoustic power travel from the cold end to the hot end, it was decided to try modeling the secondary pulse tube. The friction factor and heat transfer coefficient are calculated at each time increment and at each grid point in the regenerator from the steady-state correlations of Kays and London. These correlations are described in Kays, W. M., and London, Compact Heat Exchangers, Third Edition, McGraw-Hill, 1984. Such correlations should be useful for oscillating flow in regenerators where the amplitude of gas motion is much larger than the hydraulic diameter and the hydraulic diameter is less than the viscous penetration depth. The latter condition means the Valensi number is less than 1. Those conditions usually do not hold in pulse tubes. The Valensi number for the pulse tubes of interest here are on the order of 100. The Valensi number Va is approximately equal to the squared ratio of the tube inner radius to the viscous penetration depth, as given by formula (3):
where r is the inner radius, ρ is the gas density, ω is the angular frequency, and μ is the dynamic viscosity. For such high Valensi numbers, the friction factor and the heat transfer coefficient should be higher than those determined from steady state correlations. These correlations are described in Garaway, I., Grossman, G., “Studies in High Frequency Oscillating Compressible Flow for Application in a Micro Regenerative Cryocooler,” Adv. Cryogenic Engineering, Vol. 51, American Institute of Physics, New York, 2006, pp. 1588-1595. Because the pressure drop in the pulse tube is so small, the difference has no significant effect on most of the modeling described herein. The higher heat transfer coefficient may affect the calculation of the enthalpy flow within the pulse tube. The enthalpy results noted were used to understand general trends. However, care was taken to not rely heavily on the absolute values.
The parameters used for the modeling discussed here are given in Table 1, set forth below. All of the calculations are with 4He working fluid. Because of the relatively high temperature (30 K to 300 K) and the low pressure (1.0 MPa), real gas effects should be small. Thus, no significant differences are expected if 4He were to be replaced with 3He. For the secondary regenerator, a 6 mm diameter stainless steel tube was modeled that was filled with various mesh sizes of stainless steel screen to achieve different hydraulic diameters. Hydraulic diameters greater than about 100 μm are not practical for actual regenerators, but values up to the tube diameter were used in the calculations to observe the effect of hydraulic diameter. The porosity was kept constant at 0.68, and the cold end mass flow rate was held constant at 0.32 g/s for all values of hydraulic diameter. For the secondary pulse tube modeling, the tube diameter and the flow were varied in such a manner that the ratio of cross-sectional area to the cold end mass flow remained constant. The relative penetration of the gas at the cold end varied from about 0.18 to 0.25. The porosity was set at 0.91 to account for a thin wall.
An important parameter of the secondary regenerator or pulse tube is the heat load or heat lift that such component imposes upon the primary pulse tube warm end. The heat load is given by the sum of the time-averaged enthalpy flow and the thermal conduction in the secondary element. In analyses of entire pulse tube cryocoolers, a positive enthalpy flow is generally meant to be a flow from the compressor to the expander. That convention is maintained and a positive enthalpy and conduction flow is believed to occur from the cold end to the warm end of the secondary regenerator or pulse tube. A positive value then means a cooling effect.
The calculated temperature profile for a secondary regenerator with a 64 μm hydraulic diameter (#325 mesh) and a 4.0 mm diameter secondary pulse tube are shown in
For small 4 K refrigeration powers, a small linear compressor would be able to provide the function of a linear expander. An important property of the compressor is that its swept volume should be a close match to the required swept volume to eliminate excessive void volume, which requires a larger swept volume to extract the same amount of PV power. The behavior of a linear compressor can be modeled by constructing a force balance, where the motor force must balance the forces due to the mechanical spring, pressure, damping, and inertia.
For the example considered herein, the smallest commercially available linear compressor is used as the expander for the analysis. Table 2 set forth below, gives the parameters of this linear compressor needed for modeling it as an expander.
The preferred embodiment cooling systems generally comprise a compressor or cryocooler, a regenerator, a pulse tube, a secondary component as described herein, and an expander. As will be understood, these components are in fluid communication with one another such that a working fluid can be transferred between the components. The pulse tube generally defines a cold end which can be from about 20 K to about 4 K, and most preferably about 4 K. The pulse tube also defines a warm end which is typically from about 60 K to about 20 K, and most preferably about 30 K. The secondary component is preferably either a secondary regenerator or a secondary pulse tube. The secondary component is preferably in direct fluid communication with the warm end of the pulse tube. The expander is preferably a pressure oscillator and most preferably operated at ambient temperature. In such configurations, the pressure oscillator can be commercially available pressure oscillator. It will be understood that the expander or pressure oscillator serves as a phase shifter component.
In addition to the preferred embodiment two stage cooling systems described herein, the invention includes an array of multistage pulse tube cooling systems. For example, a three stage pulse tube cooling system utilizing one or two secondary regenerators and/or secondary pulse tubes is contemplated.
Additional details and background information concerning cryocoolers, pulse tube cooling systems and the like are provided in U.S. Pat. Nos. 6,205,812; 6,644,038; and 6,389,819. Additional information is also provided by Radebaugh, “Development of the Pulse Tube Refrigerator as an Efficient and Reliable Cryocooler,” Proc. Institute of Refrigeration, 1999-2000, p. 1-27.
Stirling-type pulse tube cryocoolers for operation at 4 K require the flow at the cold end to lag the pressure by about 30° to provide the maximum COP for the 4 K regenerator and to enable the cryocooler to operate reasonably efficient. An inertance tube at the 30 K warm end of the 4 K stage can not provide sufficient phase shift when the operating frequency is about 30 Hz or higher. Thus, a warm expander is required to provide the ideal phase shift. Commercial linear compressors can be used as the expander if they can operate at such low temperatures. As described herein, it has been demonstrated that such an expander can also be used at room temperature to provide the required phase shift, but then a secondary pulse tube or secondary regenerator is preferably placed between the warm end (at about 30 K) of the 4 K pulse tube component and the room temperature expander. A smaller expander swept volume is required when a secondary pulse tube is used as opposed to a secondary regenerator. Further investigations with a secondary regenerator and a room temperature expander have shown improved performance compared with what can be achieved with an inertance tube at 30 K. Impedance matching to the linear expander at room temperature is not very important as long as the expander has sufficient swept volume to provide the necessary phase shift between flow and pressure.
Many other benefits will no doubt become apparent from future application and development of this technology.
All patents, published applications, and articles noted herein are hereby incorporated by reference in their entirety.
It will be understood that any one or more feature or component of one embodiment described herein can be combined with one or more other features or components of another embodiment. Thus, the present invention includes any and all combinations of components or features of the embodiments described herein.
As described hereinabove, the present invention solves many problems associated with previously known systems and devices. However, it will be appreciated that various changes in the details, materials and arrangements of parts, which have been herein described and illustrated in order to explain the nature of the invention, may be made by those skilled in the art without departing from the principle and scope of the invention, as expressed in the appended claims.
The present invention is a divisional application and claims priority upon U.S. Ser. No. 13/012,040, filed Jan. 24, 2011 and it relates to pulse tube cooling systems and particularly, room temperature operation of pressure oscillators used in such systems.
Number | Date | Country | |
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Parent | 13012040 | Jan 2011 | US |
Child | 14492609 | US |