CROSS REFERENCE TO RELATED APPLICATION

This application claims priority to and the benefit of U.S. Provisional Patent Application Serial No. 62/743,482 filed October 9, 2018, entitled “Cryocooler Assemblies and Methods”, the entirety of which is incorporated by reference herein.

TECHN ICAL FI ELD

The present disclosure provides cryocooler assemblies and methods and in particular embodiments, the present disclosure provides cryocooler assemblies and methods that can be utilized in conjunction with variable temperature analytical instruments such as cryostats.

BACKG ROUN D

Cryocoolers (a.k.a. “coldhead”) have been used to vary the temperature of samples during analysis well into the low Kelvin range of temperatu res. During this variation of temperatures, vibrations can exist which can substantially impact the analysis of the sample. The present disclosure provides a cryocooler that, in at least some embodiments, reduces vibrations.

SUMMARY

Cryocooler assemblies are provided that can include : a first mass configured to generate mechanical responses; a second mass operably engaged with the first mass; and an assembly between the first and second mass, the assembly configured to allow movement of the first mass in relation to the second mass.

Methods for isolating mechanical responses within a cryocooler assembly are provided. The methods can include : generating a mechanical response about a first mass within a cryocooler assembly; suspending the first mass in relation to a second mass of the assembly; and operatively engaging the second mass as a cold source for the cryocooler assembly.

Cryocooler assemblies are provided that can include : a coldhead operatively engaged with a chamber configured to retain cryofluid; and a first thermally conductive mass thermally engaged with the cryofluid.

Methods for providing one or more cold sources from a cryocooler are also provided. The methods can include operatively engaging at least the cryofluid of the cryocooler with one or more thermally conductive masses.

DRAWINGS

Embodiments of the disclosure are described below with reference to the following accompanying drawings.

Fig. 1 is a block diagram of an analytical instru ment according to an embodiment of the disclosure.

Fig. 2 is a depiction of an assembly/instrument according to an embodiment of the disclosure.

Fig. 3 is a depiction of an assembly/instru ment according to another embodiment of the disclosure.

Fig. 4 is a depiction of an assembly/instru ment according to another embodiment of the disclosure.

Fig. 5 is a cryocooler according to an embodiment of the disclosure.

Fig. 6 is a cryocooler according to another embodiment of the disclosure.

Fig. 7 is a cryocooler according to another embodiment of the disclosure. Fig. 8 is a cryocooler according to another embodiment of the disclosure.

Fig. 9 is a cryocooler according to another embodiment of the disclosure.

Fig. 10 is a cryocooler according to another embodiment of the disclosure.

Fig. 11 is a cryocooler according to another embodiment of the disclosure.

Fig. 12 is a cryocooler according to another embodiment of the disclosure.

DESCRI PTION

The assemblies and methods of the present disclosure will be described with reference to Figs. 1 -1 2. Referring first to Fig. 1 , analytical instru ment 10 is provided that includes a sample chamber 14 in operative commu nication with a cooling pod 1 2 that may include both a cooler 16 and a pumphouse 18. While cooling pod 12 is shown housing both cooler 16 and pumphouse 1 8, this is not necessary, but may be desirable as cooler 1 6 and pumphouse 18 may be housed separately but operatively coupled to one another and/or to sample chamber 14. In accordance with an example implementation, there can be separation (thermal, vacuum/pressure, and/or physical) of sample chamber 14 from cooler 16. Cooler 16 can include an operational coldhead for example. This is just one example of an instrument or assembly that can benefit from embodiments of this disclosure.

For example, and with reference to Fig. 2, instru ment or assembly 210a can include masses 212 and 214 respectively. These masses can be operatively engaged via another assembly 216. In accordance with example implementations, both masses 212 and 214 may be in physical contact with a mounting surface 220 which may be the same or different surfaces. As a part of operating instrument or assembly 210a, a device 218 is engaged that generates mechanical responses, such as vibrations. Device 218 can be a prime mover such as a pump, motor, gas mover, etc. and/or may provide either or both of high or low frequency noise. Mass 212 can be engaged with su rface 220 via spring and damper assembly 222. Spring and damper assemblies can include any assembly that includes: only a spring, only a damper, a spring and damper, but can fu nctions to bias one mass in relation to another mass, one mass in relation to a surface, and/or both masses in relation to a surface. Spring and damper assemblies, pressure differences, and/or O-rings and/or assemblies can be utilized to suspend one mass in relation to another mass. The suspending of the masses can allow for motion between the masses in one, more, or all planes while still operatively engaging the masses. As one example, the coldhead motion in relation to the chamber of a cryocooler.

Mass 214 can be engaged with surface 220 via spring and damper assembly 224. The combination of the masses 212 and 214 with possibly different spring and damper assemblies 224 and 222 can provide a low pass filter connection to surface 220. Providing different combinations of masses and springs and dampers can provide for a purposeful mismatch in resonance frequency between masses 21 2 and 214 as they are engaged by assembly 21 6. Assembly 21 6 can include sliding complimentary components engaged by O-rings.

Referring next to Fig. 3, in accordance with an example implementation assembly 21 0b is depicted to demonstrate only one of masses 212 or 214 in physical contact with a mounting surface 220 with the other mass referenced to it. Mass 212 can be engaged with su rface 220 via spring and damper assembly 222 and mass 214 can be engaged with mass 212 via spring and damper assembly 225.

Referring next to Fig. 4, assembly 21 0c is shown that depicts a demonstration of yet another assembly configuration. Assembly 21 0c has mass 214 engaged with surface 220 via spring and damper assembly 224 and mass 212 can be engaged with mass 214 via spring and damper assembly 223.

In accordance with example implementations cryocooler assemblies 20a-20e are depicted in Figs. 5-9. Referring first to Fig. 5, a cryocooler assembly 20a is shown that includes a coldhead 22 that is arranged as a first stage 24 and second stage 26 coldhead device. Coldhead 22 can be operatively coupled to a compressor system providing coolant fluid such as but not limited to nitrogen and/or helium, for example, or alterations thereof. In accordance with traditional operations, the use of these fluids with the compressor and the coldhead can yield low Kelvin temperatures at the second stage 26 of the coldhead. The coldhead can also be configured to provide a heat sink or cold source that can be linked to one or more masses to remove heat from or provide cooling to the one or more masses.

System 20a can include a chamber 27 that can be maintained at an interior pressure 30 that is substantially different than the exterior pressu re 32. This pressure differential can be utilized to provide suspension force on the coldhead 22 within chamber 27 as desired. Accordingly, coldhead support structures 34 can be placed about housing 28 of chamber 27 to provide for a sliding engagement of structures 34 and housing 28, thereby suspending one mass in relation to another mass

Residing between housing 28 and coldhead support structu res 34 can be a sealing structure 36 such as an O-ring or dual O-ring assembly. Sealing structu re 36 can have improved fu nctionality when compared to other implementations such as a rigid tube or bellows connection. For example, high resonance frequencies can be more effectively attenuated in all directions and modes (X-Y-Z translations, tip, tilt, and torsion between bodies 34 and 28) ultimately resulting in less mechanical energy transfer to body 28 and a lower resonance frequency of body 28. Referring to Fig. 6, assembly 20b is depicted that includes spring and damper assemblies 38-41 that are arranged according to an embodiment of the disclosure. In combination, sealing structure 36 and assemblies 38 and 40 can maintain the pressu re differential between the interior and exterior volumes, but also provide a damping of vibrations generated about the coldhead thus limiting the vibrations extending to a sample that is supported by a mass which is coupled to the coldhead. Accordingly, support structu re 34 can include upper spring and lower spring and damper assemblies 38 and 40, and coldhead 22 can be mechanically insulated from housing 28. These spring and damper assemblies 38 and 40, as well as other spring and damper assemblies can be tuned specifically to attenuate vibration transfer from the coldhead and coldhead support to the rest of instru ment, including surface 220 to which the spring and dampers 38 and 40 are mou nted. Also, the combined system of spring and damper assemblies 38 and 40 along with the coldhead mass can be purposefully de-tuned from the housing 28 mass and the spring and damper assemblies thus reducing the transmission of vibration from the coldhead to the housing 28 when mou nted on common surface 220. For example, housing 28 can include upper spring and damper assembly 39 and lower spring and damper assembly 41 that can be tu ned specifically, according to the mass and resonant frequency of the chamber, to reduce the vibrations of the chamber.

Referring to Fig. 7, assembly 20c depicts another configuration that provides for the spring and damper assemblies 39 mounted between the housing 28 and support structure 34 that is operatively engaged with su rface 220 via spring and damper assemblies 38. Referring to Fig. 8, assembly 20d depicts another configu ration having spring and damper assemblies 39 operatively engaged between support structure 34 and housing 28. Flousing 28 may also have spring and damper assemblies 41 operatively engaged with surface 220. Referring to Fig. 9, assembly 20e depicts another configuration without a spring and damper assembly engagement to support structure 34. Assembly 20e can rely on the pressure differential between interior pressu re 30 and exterior pressure 32 to support the mass of coldhead 22 and support structure 34. Accordingly, only housing 28 may be operably engaged with the surface 220 via spring and damper assemblies 41 in this specific embodiment.

In accordance with example implementations, coldhead 22 and supports 34 of Figs 5-9 can correspond to mass 212 of Figs. 2-4, and housing 28 of Figs. 5-9 can correspond to mass 214 of Figs. 2-4. The arrangement of spring and damper assemblies can likewise correspond according to example implementations.

Referring next to Figs 1 0-12, cryocooler assemblies 400a-b are shown providing at least some of the contemplated cryocooler configu rations. Each cryocooler can include a coldhead 22 having operable stages 24 and 26, for example. About the coldhead and stages can be a housing 28 that defines a chamber 27. In accordance with example operations, within chamber 27 a temperature gradient 25 can exist. For example, at the lower most portion of the chamber a liquid form of the cryofluid can exist and this may have the lowest most temperature of the cryofluid within the chamber. As the gradient extends away from the lower most portion of the chamber, the cryofluid may exist as a gas/liquid or as a gas and these temperatu res are different, (higher) than the temperatu re of the liquid at the lower most portion of the chamber.

In accordance with example implementations, thermally conductive masses, such as masses 42, 44, 60, and/or 62 can be thermally engaged with the cryofluid within the chamber. This thermal engagement can be convective, conductive, and/or a combination of both. For example, masses 42, 44, 60, and/or 62 can be thermally engaged via convections 45, 47, 65, and/or 67 respectively.

Accordingly, these masses have the temperatu re of the cryofluid with which they are thermally engaged. In accordance with other embodiments, these masses may be conductively engaged with both the cryofluid and the coldhead via respective thermal links 46, 48, 64, and/or 66. These thermally conductive links and/or masses may be constructed of thermally conductive materials such as copper.

In accordance with example implementations, the masses can be arranged in relation to the cryofluid to maintain the masses at a desirable temperatu re for use as a cold source for discrete portions of a cryoanalytical device.

Particular embodiments of the cryocooler assemblies can include at least one thermal link extending from a coldhead 22 within chamber 27. Referring to Fig. 1 0, assembly 400a is shown that includes separate thermal links 46 and 48 extending from corresponding first and second stages 24 and 26 of coldhead 22 within chamber 27. While two links are depicted in this configuration, a single link from the coldhead is contemplated. As shown, specific portions of the coldhead can be in thermal connection with specific masses 42 and 44 via respective thermal links 46 and 48. In this particular embodiment, the spring and damper assemblies can be tuned to minimize vibrations transfer from the coldhead to mass 42 and mass 44. Again, this thermal communication can include, but is not limited to: flexible conductive lines; and/or conduction and/or convection through the cryofluid within chamber 27. The thermal links can allow for large relative motion between the masses 42 and 44 and the respective thermal connection points thus leading to an additional mechanical isolation. Masses 42 and 44 can also be suspended from coldhead stages 24 and 26 through a spring and damper assembly that is not depicted here, or mou nted to housing 28 through a spring and damper assembly that is not depicted, but also contemplated.

Referring next to Fig. 11 , assembly 400b is depicted that includes portions 42 and 44 of chamber housing 28. These portions can be thermally conductive while other portions of chamber housing 28 are insulative. In accordance with example implementations, thermal gradient 25 may exist in the cryofluid contained within the chamber 27 and the thermal masses 42 and 44 may be positioned at different heights, for example near the second stage 26 and/or first stage 24 of the coldhead for example, to utilize different temperatures along the temperature gradient of the fluid, and the associated cooling powers. Accordingly, thermal links 45 and 47 can provide cold source links as a liquid or gas thermal link between the contents of the chamber the proximate mass.

Referring next to Fig. 1 2, assembly 400c is depicted in accordance with another implementation, masses 52 and 54 are in thermal communication with thermally conductive portions 60 and 62 respectively via thermal links 56 and 58 These contacts are in thermal connection, via flexible conductive lines and/or conduction and/or convection through the cryofluid, with the coldhead via additional links 64 and 66 and/or convections 65 and 67. As shown, spring and damper assemblies 39 and 41 can be tu ned to minimize vibrations transfer from the coldhead to mass 52 and mass 54. In accordance with example implementations, masses 52 and/or 54 can define portions of a cryoanalytical device utilizing and/or associated with the cryocooler assembly. For example, the portions of the cryo analytical device can include a radiation shield or a sample mou nting su rface or fixture.