The invention relates to a cryogenic cooling system, in particular a cryogenic cooling system with a self-supporting demountable insert.
Cryogenic cooling systems are commonly used to perform experiments at low temperatures below 100 Kelvin. Systems are generally customised for a specific experiment by installing experimental apparatus in a particular arrangement. Installation of experimental apparatus can be difficult and time consuming, commonly requiring the use of cranes or elevated platforms to access the system. Furthermore, testing is generally required after the installation of equipment to ensure it is functioning satisfactorily, which can take a significant amount of time. The more time spent installing and troubleshooting, the less time spent collecting experimental data.
Cryogenic cooling systems can reach millikelvin temperatures when in use, typically by including a number of platforms which are held at intermediate temperatures between room temperature and millikelvin temperatures. In this way, the cooling can be staged, such that the final platform of the system can provide continuous cooling to millikelvin temperatures. Installed experimental apparatus and other components of the system can provide a path from room temperature to the final platform. In order to prevent unintentional heating through these components, each platform provides a thermal sink to remove additional heat.
It is possible for experimental services to be assembled on a module outside a system and installed pre-assembled. This is typically faster than direct installation of experimental services. However, it is important for the module to be well thermalised, so that millikelvin temperatures can be obtained. In the prior art, thermalisation is achieved using clamps and/or complex and extensive adjustment processes.
It is the case that a minor offset will result in poor thermalisation within the system.
Low temperature physics experiments are becoming increasingly complex, and the experimental services required to perform the experiments is consequently increasing. Quantum Information Processing (QIP) experiments, for example, use radio-frequency (RF) wiring to address devices with large numbers of qubits. As the number of qubits scales up, the amount of RF wiring required correspondingly increases. Cryogenic cooling systems are expected to accommodate the growing amounts of experimental services. One way the growing demands can be accommodated is by providing modular upgrades for a core system. However, manufacturing tolerances can accumulate to result in mismatched joints and poorly thermalised platforms within the cryogenic cooling system, thus requiring extensive minor adjustments to improve performance.
It is desirable to have a more convenient way of installing experimental services in a cryogenic cooling system.
A first aspect of the invention provides a cryogenic cooling system comprising, when in use: a primary insert comprising: a plurality of primary plates, each primary plate having a primary contact surface; and one or more primary connecting members arranged so as to connect the plurality of primary plates; a demountable secondary insert comprising: a plurality of secondary plates, each secondary plate having a secondary contact surface; and one or more secondary connecting members arranged so as to connect the plurality of secondary plates such that the secondary insert is self-supporting; and one or more adjustment members; wherein the one or more adjustment members are configured such that, when in use, when the secondary insert is mounted to the primary insert, the adjustment members cause the primary and secondary contact surfaces of the respective primary and secondary plates to be brought into conductive thermal contact.
Advantageously, the system comprises adjustment members which cause the primary and secondary contact surfaces of the respective primary and secondary plates to be brought into conductive thermal contact with each other. This removes the need for numerous minor adjustments to overcome a misalignment between two portions of a cryogenic cooling system such that they are in effective thermal communication. When demounted, the secondary insert can also be moved with respect to the primary insert as a self-supporting body, which further simplifies the mounting and demounting process. For example, each plate of the secondary insert can be aligned with respect to the corresponding plate of the primary insert in a single step.
The one or more adjustment members may form part of the primary insert. In this case, the adjustment members may form part of the plurality of primary plates, or form part of the one or more primary connecting members, or form part of both the plates and the connecting members. Similarly, the one or more adjustment members may form part of the secondary insert. In this case, the adjustment members may form part of the plurality of secondary plates, or form part of the one or more secondary connecting members, or form part of both the plates and the connecting members. It is also possible for the adjustment members to form part of the primary insert and the secondary insert. Alternatively the adjustment members may take the form of fasteners that are configured to couple corresponding plates of the primary and secondary inserts. The choice of location of the adjustment members may depend on a specific implementation. For example, if the secondary insert is designed to accommodate rigid experimental apparatus, the position and type of adjustment member will be chosen accordingly.
The primary and secondary plates typically extend in a generally planar manner and are connected in use along mutually adjacent peripheral surfaces of the plates, and these may be stepped. Preferably, the conductive thermal contact between a primary plate and the corresponding secondary plate is provided by area contact between conformal planar regions of the respective primary and secondary contact surfaces. Each of the primary and secondary plates may comprise a flange. When a primary plate is brought into contact with the corresponding secondary plate, a lower surface of the flange of the primary plate matches an upper surface of the flange of the secondary plate to form a continuous structure. Typically, the primary plates and the secondary plates are formed from a high conductivity material and thus a joint in which the plates are intimately connected over a large area will provide a good thermal connection across the joint.
The adjustment members typically cause the primary and secondary contact surfaces of the respective primary and secondary plates to be brought into conductive thermal contact by accommodating a misalignment between each of the plurality of secondary plates of the demountable secondary insert and the corresponding primary plate of the primary insert. There may be a misalignment between primary and secondary plates as a result of manufacturing tolerances. Any misalignment between plates, if left unadjusted, will reduce the thermal conductance between plates.
Although the cryogenic cooling system comprises both a primary insert and a secondary insert, the secondary insert (or, alternatively, the primary insert) is demountable and thus is removable from the system. When the secondary insert is in a demounted state, the secondary plates are typically spatially positioned with respect to one another in a secondary configuration. The secondary insert is self-supporting in its demounted state, and the spacing between adjacent plates within the secondary insert may be determined by the secondary connecting members. Similarly, when the secondary insert is in a demounted state, the primary plates are typically spatially positioned with respect to one another in a primary configuration. The spacing between adjacent plates within the primary insert may be determined by the primary connecting members.
During a mounting process, the secondary insert may be mounted to the primary insert. A plate of the secondary insert is preferably configured to be brought into contact with a corresponding plate of the primary insert. However, there may be a misalignment between the above-mentioned plates. The misalignment may be the offset between the plane of a secondary plate and the plane of the corresponding primary plate in the respective primary and secondary configurations. Each pair of plates may have a different misalignment, and the misalignment may be positive or negative. Consequently, each adjustment member may provide a different level of adjustment, and typically is capable of providing a range of motion of at least 2 millimetres, preferably at least 4 millimetres in order to accommodate the misalignment.
The secondary insert is demountable from the cryogenic cooling system. The secondary insert may be fully demounted, i.e. all of the plates of the secondary insert may be separated from the primary insert and removed. Optionally, the secondary insert may only be partially demounted. If the secondary insert is partially demounted, some of the plates of the secondary insert remain attached to the primary insert, whilst the remainder of the plates of the secondary insert are removed from the primary insert. Preferably, one or more of the secondary connecting members are removable such that two or more of the plurality of secondary plates may be detached from the demountable secondary insert as a unitary, self-supporting body or assembly.
The secondary insert may comprise a first secondary plate, a second secondary plate and a third secondary plate connected using secondary connecting members, wherein the second secondary plate is positioned between the first and the third secondary plate. If the secondary connecting members connecting the second secondary plate and the third secondary plate are removed, the second secondary plate and the first secondary plate may be removed as a unitary structure. The partially demounted secondary insert (the first and second secondary plates) is preferably self-supporting in a similar way to the self-supporting nature of the fully demounted secondary insert.
The demountable nature of the secondary insert advantageously allows the secondary insert to be modified away from the cryogenic cooling system. However, in cases in which it is not necessary to remove the entire secondary insert, it may be beneficial to leave a portion of the secondary insert attached to the primary insert. For example, as low-temperature experiments are typically performed in a vacuum, one of the joints between the primary insert and the secondary insert may form part of a barrier between atmospheric pressure and low pressure. Therefore, additional sealing may be required such as the use of an o-ring or other vacuum seal such as to reduce the possibility of any gas leaks. It may be beneficial to leave the plates forming the above-mentioned barrier in place to avoid repeatedly reforming the seal.
An advantage of the secondary insert being demountable from the cryogenic cooling system is the ability to assemble, modify and test experimental services mounted to the secondary insert away from the cryogenic cooling system. Furthermore, the modifications may only need to be performed on two, or any number of, plates of the secondary insert. It may be easier and therefore preferable to partially demount the secondary insert, only removing the necessary plates.
Typically, experimental services are positioned within the cryogenic cooling system and are used to perform experiments at low temperatures. Preferably, one or more the plurality of secondary plates is configured to accommodate experimental apparatus. This is particularly advantageous if the experimental apparatus mounted to the secondary insert is complex and time-consuming to assemble. The experimental services can hence be assembled and tested away from the cryogenic cooling system before being mounted to the primary insert.
The cryogenic cooling system can be used for low temperature experimental procedures and cooling can be achieved using a number of refrigeration apparatus. It is particularly desired for such systems to achieve millikelvin temperatures. To this end, a dilution unit preferably forms part of the cryogenic cooling system, for example the primary insert may comprise a dilution refrigerator or components thereof. The dilution refrigerator may be thermally coupled to one or more plates of the primary insert. Alternatively the primary insert may comprise a helium-3 refrigerator or a 1 kelvin pot. In such a way, one or more plates of the primary insert may attain millikelvin temperatures. The conductive thermal contact between the primary insert and the secondary insert ensures that the secondary insert may reach similarly low temperatures during operation.
One or more of the primary plates or the secondary plates may comprise a rigid portion and one or more deformable portions. Preferably, the deformable portions are deformable with respect to the rigid portions to accommodate the misalignment. The one or more adjustment members may hence comprise the one or more deformable portions. During the mounting of the demountable secondary insert to the primary insert, the one or more deformable portions may locally deform so as to cause the conductive thermal contact. The deformable portions of the plates may be provided at the plate edges, for example in the form of flanges. One advantage of this mode of adjustment is the ability to maintain the primary and/or secondary configurations within the respective inserts. For example, operation of the adjustment member may not change the separation between adjacent primary plates of the primary insert or adjacent secondary plates of the secondary insert. In practice this means that the primary or secondary inserts respectively can remain fixed and can therefore accommodate rigid experimental apparatus which is mounted to more than one plate. Similarly, the separation between corresponding plates of the primary and secondary inserts respectively can remain fixed. The deformation may be configured to occur locally, in pre-defined areas of a plate, such that experimental apparatus is not damaged, but conductive thermal contact is nevertheless achieved. The deformable portions may form part of the primary plates. Alternatively, the deformable portions may form part of the secondary plates. The deformable portions may optionally form part of both the primary plates and the secondary plates.
When the secondary insert is in a demounted state, the primary and secondary inserts may have respective primary and secondary configurations as described above. If the adjustment is achieved through local deformation, it is possible for the primary and secondary configurations to be maintained even when the demountable secondary insert is in a mounted state. The one or more adjustment members may alternatively cause one or both of the primary or secondary configurations to be adjustable so as to cause the conductive thermal contact. For example, the one or more adjustment members are configured to change the separation between adjacent primary plates or adjacent secondary plates. This may be achieved by configuring each of the one or more primary connecting members or secondary connecting members to deform so as to accommodate the misalignment between plates.
The one or more adjustment members may form at least part of one or more of the primary connecting members or secondary connecting members. For example, the one or more adjustment members may form respective flexible portions of the primary or secondary connecting members. During the mounting of the secondary insert to the primary insert, a misalignment could be accommodated by placing the secondary connecting members under a compressive or tensile load. In response to the load, the secondary connecting members would deform thus causing the conductive thermal contact by bringing the secondary plate into alignment with the corresponding primary plate. Similarly, a misalignment could be accommodated through the deformation of flexible primary connecting members.
Alternatively, the one or more adjustment members may be configured to allow movement of the one or more primary plates with respect to the one or more said primary connecting members, or the one or more adjustment members may be configured to allow movement of the one or more secondary plates with respect to the one or more said secondary connecting members. For example, the primary or secondary connecting members may be rotatable so as to change the separation between adjacent primary plates or adjacent secondary plates using the one or more adjustment members. This adjustment may generally be achieved where an end of the primary or secondary connecting members comprises a screw or tapped portion. In this case the adjustment member may comprise said screw or tapped portion of a connecting member in combination with a receiving member configured to engage with the screw or tapped portion so as to adjust the separation between adjacent plates of the primary or secondary insert.
Preferably, the primary and secondary connecting members are thermalised at the respective primary and secondary plates. Typically there is a heat load conducted from room temperature along the primary and/or secondary connecting members to the lower temperature stages of the system. Thermalisation at the plates advantageously intercepts this heat load, thereby forming a thermal sink that enables distal stages of the primary or secondary insert to obtain lower temperatures during operation of the system. Effective thermalisation of the primary connecting members may be achieved through the use of one or more primary shims, each said primary shim thermally coupling a said primary plate to one or more said primary connecting members and configured to allow movement of the said primary plate with respect to the said one or more primary connecting members. Similarly, effective thermalisation of the secondary connecting members may be achieved through the use of one or more secondary shims, each said secondary shim thermally coupling a said secondary plate to one or more said secondary connecting members and configured to allow movement of the said secondary plate with respect to the said one or more secondary connecting members.
Further aspects of the invention will now be described. Any features discussed in connection with one aspect are equally applicable in respect of the remaining features and each aspect shares similar advantages.
A second aspect of the invention provides a demountable secondary insert for use in a cryogenic cooling system in accordance with the first aspect.
A third aspect of the invention provides a method of operating the system according to the first aspect, wherein the secondary insert comprises a first secondary plate, a second secondary plate and a third secondary plate, a first secondary connecting member connecting the first secondary plate to the second secondary plate, and a second secondary connecting member connecting the second secondary plate to the third secondary plate, and wherein the primary insert comprises three primary plates, each said primary plate corresponding to a respective secondary plate of the secondary insert, the method comprising: mounting the secondary insert to the primary insert such that secondary plates are thermally coupled to the corresponding primary plates using the one or more adjustment members; and partially demounting the secondary insert from the primary insert, wherein partially demounting the secondary insert comprises: removing the first secondary connecting member from the secondary insert; and removing the second secondary plate, the third secondary plate and the second secondary connecting member from the primary insert as a unitary self-supporting assembly, without removing the first secondary plate from the corresponding plate of the primary insert.
Embodiments of the invention will now be described with reference to the accompanying drawings in which:
The cryogenic cooling system comprises cooling apparatus. The cooling apparatus cools the cryogenic cooling system from room temperature to an operational base temperature. The cryogenic cooling system in the first embodiment is substantially cryogen-free (also referred to in the art as “dry”) in that it is not principally cooled by contact with a reservoir of cryogenic fluid. However, despite being substantially cryogen-free, some cryogenic fluid is typically present within the cryostat when in use, including in the liquid phase, as will become clear. In this embodiment, the cooling is achieved by use of a mechanical refrigerator and a dilution unit. The mechanical refrigerator may be a pulse-tube refrigerator (PTR), a Stirling refrigerator, or a Gifford-McMahon (GM) refrigerator.
In this embodiment, the mechanical refrigerator is a PTR 40, and is thermally coupled to the first thermal stage 1 and the second thermal stage 2. Each thermal stage 1-5 is formed from a high conductivity material such as copper and has a different operational base temperature. The first thermal stage 1 is thermally coupled to a first PTR stage 41 and attains an operational base temperature of about 50 to 70 kelvin. The second thermal stage 2 is thermally coupled to a second PTR stage 42 and attains an operational base temperature of about 3 to 5 kelvin. In this embodiment, the second PTR stage 42 forms the lowest temperature stage of the PTR 40.
The third thermal stage 3, fourth thermal stage 4 and fifth thermal stage 5 are thermally coupled to a dilution unit 8. The cooling of the third, fourth and fifth thermal stages 3, 4, 5 is achieved through operation of the dilution unit 8, in which an operational fluid is circulated around a cooling circuit 60. The operational fluid is typically a mixture of helium-3 and helium-4. The operational fluid is pumped around the cooling circuit 60 which comprises a condensing line 61 and a still pumping line 62 using a compressor pump 63 and a turbomolecular pump 64. The operational fluid can be stored in a storage vessel 65 and supplied to the cooling circuit 60 using a supply line 66. The third thermal stage 3 is thermally coupled to a still 10 which forms part of the dilution unit 8. The operational base temperature of the third thermal stage 3 is typically 0.5 to 2 kelvin. The fifth thermal stage 5 is thermally coupled to a mixing chamber 9 of the dilution unit 8. The operational base temperature of the fifth thermal stage 5 is typically 3 to 30 millikelvin. The fourth thermal stage 4 forms an intermediary stage between the third and fifth thermal stages 3, 5 and has an operational base temperature of about 50 to 200 millikelvin.
In use, a number of heat radiation shields 56-58 are attached to the thermal stages 1-5, wherein each shield encloses each of the remaining lower base-temperature components. The first heat radiation shield 56, second heat radiation shield 57 and third heat radiation shield 58 are attached to the first thermal stage 1, second thermal stage 2, and third thermal stage 3 respectively. This reduces any unwanted thermal communication between the thermal stages 1-5 and allows the stages to attain different operational base temperatures.
The cryogenic cooling system of
A cryogenic cooling system as described can be used to perform experiments at low temperatures, generally below 100 kelvin. Although not shown in
An advantage of mounting the experimental services to the secondary insert 28 arises from the ability to remove the secondary insert 28 from the cryogenic cooling system. Assembly and preliminary tests can be performed ‘on the bench’, outside the cryogenic cooling system in which the experiment will be performed. In this way, modifying or updating the experimental services to run a different experiment can be performed relatively quickly and easily. Low-temperature experiments using a cryogenic cooling system such as a dilution refrigerator typically take days, weeks or months to perform. Modifications to the experimental services within the system lead to experimental down time, i.e. time during which the cryogenic cooling system is not at operational base temperature, as the modifications typically need to be performed at room temperature. The ability to manipulate experimental services on the demounted secondary insert 28 on the bench (remote from the system itself) reduces the experimental down time. For example, multiple secondary inserts may be provided for use with a given cryogenic cooling system. Adjustments may be made to experimental services on a first secondary insert under atmospheric conditions whilst a cryogenic environment is maintained in the system for performing experiments on a second secondary insert.
Embodiments of the invention also provide adjustment members which cause the primary insert 18 and the secondary insert 28 to be brought into conductive thermal contact. Good thermal contact is important to achieve when performing low temperature measurements. In the presence of a heat flux, for example as generated by operation of a cooling source, a temperature gradient will naturally arise between the primary insert 18 and the secondary insert 28. The difference in temperature between these components will be proportional to the heat flux and inversely proportional to the thermal conductance. For any practical experiment there is a limit to the heat flux that can be applied to the system (as the cooling power available from either of the PTR stages 41, 42 or the dilution refrigerator 8 is finite). The thermal conductance of a joint will vary depending on numerous factors including its temperature and contact pressure. The adjustment members are typically configured to limit the temperature difference between corresponding stages of the primary and secondary inserts 18, 28, for example to within 2%, and preferably within 1%, of the absolute temperature of the higher temperature stage. This is achieved by making the thermal conductance between these stages sufficiently high. For example, where the second thermal stage 2 is cooled to 4 kelvin by the second PTR stage 42 (at a cooling power of 1 watt), the adjustment member for the second thermal stage 2 may ensure that the temperature difference between corresponding primary and secondary plates of the second thermal stage 2 does not exceed 40 millikelvin. The thermal conductance between primary and secondary plates of the second thermal stage 2 is therefore approximately 25 W/K at 4 kelvin. Similarly, where the fifth thermal stage 5 is cooled to 100 millikelvin by the mixing chamber 9 (at a cooling power of 400 microwatts), the adjustment member of the fifth thermal stage 5 may ensure the temperature difference between corresponding primary and secondary plates of the fifth thermal stage 5 does not exceed 1 millikelvin. The thermal conductance between primary and secondary plates of the fifth thermal stage 5 is therefore approximately 0.4 W/K at 0.1 kelvin.
The fact that there is a difference in thermal conductance expected at the second thermal stage 2 and the fifth thermal stage 5 is due to the temperature dependence of a joint, as discussed further in “Pressed copper and gold-plated copper contacts at low temperatures—A review of thermal contact resistance” by R. C. Dhuley, published in Cryogenics 101 (2019) 111-124. The thermal conductance of a given joint will decrease with temperature. However as the practical heat flux that can be applied between each primary and secondary plate in the respective primary and secondary inserts 18, 28 also decreases with temperature, all of the mounting arrangements between the primary and secondary plates can be designed and mounted in the same way to provide acceptable performance at each thermal stage 1-5.
A variety of adjustment members are envisaged and embodiments facilitating different methods of adjustment will be described.
The inner and outer primary plates 11-15, 16 and primary rods 17 form part of a primary insert 18. The inner and outer secondary plates 21-25, 26 and secondary rods 27 form part of a secondary insert 28. The secondary insert 28 is demountable from the cryogenic cooling system and, in particular, the primary insert 18. When the secondary insert 28 is in a demounted state, it forms a self-supporting assembly, which does not require any additional support structures to maintain its original configuration and can be removed from the primary insert 18 as a unitary body.
The designs of the secondary insert 28 and primary insert 18 are such that good thermal contact will be achieved between any secondary insert 28 and primary insert 18 when the secondary insert 28 is in a mounted state. It is important to ensure effective thermalisation between corresponding plates in the primary insert 18 and secondary insert 28 so that any cooling applied to one of the primary or secondary plates can be effectively applied to the other of the secondary or primary plates.
Achieving good thermal contact between any secondary insert 28 and primary insert 18 when the secondary insert 28 is in a mounted state is not trivial. During manufacture of a primary insert 18 or a secondary insert 28, the relative positioning of the inner and outer primary plates 11-15, 16 and the inner and outer secondary plates 21-25, 26 within their respective inserts 18, 28 may vary within certain manufacturing tolerances, even if made to the same specification. Small differences can lead to a misalignment, i.e. an offset between the plane of a secondary plate and the plane of the corresponding primary plate when the secondary insert 28 is brought into a mounted position. Any such misalignment, even if small, can lead to poor thermal contact. This is of particular importance at low temperatures such as the operational base temperatures of the third, fourth and fifth thermal stages 3, 4, 5.
In order to achieve good thermal contact between corresponding plates in the primary insert 18 and secondary insert 28, the cryogenic cooling system also comprises adjustment members (examples of which will be described in further detail below) which cause the inner primary plates 11-15 and inner secondary plates 21-25 to be brought into conductive thermal contact when the secondary insert 28 is in a mounted state thus accommodating a misalignment. The adjustment members may form part of the primary insert 18 or part of the secondary insert 28 or part of both.
In
In this embodiment, the cooling apparatus is attached to the primary insert 18. The cooling apparatus includes a PTR 40, comprising a first PTR stage 41 thermally coupled to the first inner primary plate 11 of the first thermal stage 1 and a second PTR stage 42 thermally coupled to the second inner primary plate 12 of the second thermal stage 2. The cooling apparatus further comprises a dilution unit 8, wherein a still 10 of the dilution unit 8 is thermally coupled to the primary plate 13 of the third thermal stage 3 and a mixing chamber 9 of the dilution unit 8 is thermally coupled to the primary plate 15 of the fifth thermal stage 5. In an alternative embodiment, the cooling apparatus is attached to the secondary insert. For example, the dilution unit may alternatively be mounted to the inner secondary plates 23, 24, 25 of the third, fourth and fifth thermal stages 3, 4, 5.
The inner and outer plates 11-15, 16 of the primary insert 18 are aligned along an axis 39 extending normal to the inner and outer primary plates 11-15, 16 in a primary configuration. Similarly, the inner and outer plates 21-25, 26 of the secondary insert 28 are aligned and spatially dispersed along a central axis normal to the inner and outer plates 21-25, 26 of the secondary insert 28 in a secondary configuration. There may be an offset between the plane of a secondary plate and the plane of the corresponding primary plate in the respective primary and secondary configurations, referred to as a misalignment. Each of the inner secondary plates 21-25 is configured to be brought into conductive thermal contact with its corresponding inner primary plate 11-15 when the secondary insert 28 is mounted to the primary insert 18, thus accommodating any misalignment. Such conductive thermal contact is caused by adjustment members. The outer secondary plate 26 forms a vacuum seal with the outer primary plate 16, for example through use of o-rings although any suitable sealing mechanism is possible.
The installation of the secondary insert 28 into the cryogenic cooling system will now be described with reference to
Each edge piece 31-35 is shaped so as to shield lower base-temperature components from excess radiation. As can be seen from
The secondary insert 28 of the cryogenic cooling system is demountable from the primary insert 18.
Whilst the secondary insert 28 is in a demounted position, modifications can be made to the secondary insert 28 and particularly the experimental services mounted to the secondary insert 28. This is practically easier for the user to achieve in the demounted position. Modifications to the secondary insert 28 may include, for example, updating or testing the experimental services mounted to the secondary insert 28. If desired, an upgraded secondary insert 28 may then be mounted to the primary insert 18. Furthermore, it may be advantageous to have more than one secondary insert 28 in order to have one secondary insert 28 in operation, i.e. in a mounted state and in experimental use, and one or more secondary inserts 28 on the bench, i.e. in a demounted state. Whilst in a demounted state, the experimental services on the secondary insert 28 can be modified or upgraded more easily. The experimental services on the demounted secondary insert 28 can be tested at room temperature, or the secondary insert 28 can be mounted into a donor cryostat to test the experimental services at low temperatures. The above testing, assembly, modification and upgrades can be performed in parallel to an experiment being performed in the cryogenic cooling system.
As described above, the secondary insert 28 forms a tiered assembly. The spatial distribution of the inner and outer secondary plates 21-25, 26 within the assembly defines five inter-plate spaces 51-55 as shown in
In
In
Depending on the experimental circumstances, it may only be necessary to test or modify only a subset of the secondary plates 21-26 of the secondary insert 28. Partial removal of the secondary insert 28 is therefore advantageous as it allows for more flexible preparation and testing of experimental services. In addition, re-installation of a part of the secondary insert 28 as opposed to the whole secondary insert 28 is less complex for a user to perform. The cryogenic cooling system can be operated with the inner secondary plates 21-25 removed. However, if the inner secondary plates 21-24 of any of the first to fourth thermal stages 1-4 are removed, then they should generally be replaced with blanks to reduce radiation transfer between the thermal stages.
Experimental services can be mounted to the cryogenic cooling system.
As described above, secondary inserts may be wholly or partially demounted from a cryogenic cooling system and inserted into another cryogenic cooling system. There may be a misalignment between each inner secondary plate 21-25 and the corresponding inner primary plate 11-15 when the secondary insert 28 is brought into a mounted position, which can lead to poor thermal contact. In order to ensure good thermal contact, the cryogenic cooling system comprises adjustment members. Possible adjustment members will now be described with reference to
The flanges 44 are separated from the rigid central part 43 by a linking portion 45. The linking portion 45 is a relatively thin strip of the first inner secondary plate 21 extending along the length of the flange 44 and which forms a pivot about which the flange 44 can move. The first inner secondary plate 21 further accommodates four receiving holes 46 for positioning the secondary rods 27, although of course the number of receiving holes 46 may vary depending on the number of secondary rods 27 used.
In the first embodiment, the flanges 44 are configured to deform when a load is applied so as to cause the first inner primary plate 11 and the first inner secondary plate 21 to be brought into conductive thermal contact. Localised deformation allows rigid experimental apparatus to be mounted to the secondary insert 28, such as an ultra-high vacuum port. Such rigid apparatus may, once mounted, effectively determine the separation between two or more of the inner or outer secondary plates 21-25, 26. In this embodiment, the rigid apparatus is mounted to the rigid central part 43 of the first inner secondary plate 21, and the flanges 44 provide a deformable portion thus forming the adjustment members. The localised deformation of the flanges 44 accommodates any misalignment between the first inner primary plate 11 and the first inner secondary plate 21.
The inclusion of a rigid central part 43 of an inner secondary plate advantageously allows rigid experimental apparatus to remain unaffected by any adjustment required whilst ensuring effective thermalisation between the secondary insert 28 and the primary insert 18.
The first inner secondary plate 21 comprises a rigid central part 43, a flange 44 and a linking portion 45. The second secondary plate 22 comprises a rigid central part 43′, a flange 44′ and a linking portion 45′. Primed reference numerals are used to designate similar apparatus features between the second inner secondary plate 22 and the first inner secondary plate 21. The first and second inner secondary plates 21, 22 both take the form shown by
In an alternative embodiment, the flanges may be positioned on the plates of the primary insert 18, instead of the secondary insert 28. This may be particularly advantageous if there are multiple interchangeable secondary inserts 28 for a cryogenic cooling system, some of which may not comprise adjustment members. In another alternative embodiment, the flanges 44 may be positioned on the plates of the primary insert 18 and the secondary insert 28. This may advantageously allow a larger possible misalignment as the deformation could occur on both sides.
In this embodiment, the deformation of the flanges 44, 44′ can accommodate the misalignment between d1 and d2 whilst the rigid central parts 43, 43′ of the first inner secondary plate 21 and the second inner secondary plate 22 remain in a fixed position with respect to each other. The first inner primary plate 11 and the second inner primary plate 12 also remain in a fixed position with respect to each other before and after the mounting process.
In the second embodiment, the secondary rods 127 are configured to deform when a compressive or tensile load is applied so as to adjust the separation between the adjacent inner secondary plates 121, 122. This movement accommodates any misalignment between the corresponding plates of the primary and secondary inserts 118, 128. In this embodiment, the primary rods 117 are rigid and therefore the separation between adjacent plates in the primary insert 118 is fixed. The secondary rods 127 are formed from stainless steel and curved to allow deformation as described. The deformation of the secondary rods 127 causes each of the inner secondary plates 121-125 to be brought into conductive thermal contact with the corresponding inner primary plates 111-115.
In
In
In the second embodiment as described above with reference to
In an alternative embodiment, the primary rods may be configured to deform when a compressive or tensile load is applied, as described above in relation to the secondary rods 127, and the secondary rods may be rigid thus fixing the position of the inner and outer secondary plates with respect to one another. This may make the secondary insert more secure in a demounted state.
In
In a demounted state, the first inner secondary plate 221 and the second inner secondary plate 222 are positioned on the shoulders 229, 229″ of the secondary rod 227 and lower secondary rod 227″ respectively. A first grub screw 230 is positioned between the secondary rod 227 and the upper secondary rod 227′. An upper portion of the secondary rod 227 and a lower portion of the upper secondary rod 227′ are tapped so as to engage with the first grub screw 230. A second grub screw 230′ is positioned between the secondary rod 227 and the lower secondary rod 227″. An upper portion of the lower secondary rod 227″ and a lower portion of the secondary rod 227 are tapped so as to accommodate the second grub screw 230′. It is this combination of the tapped portion of a secondary rod and the corresponding grub screw with which it engages that forms the adjustment member in this embodiment. In an alternative embodiment, the primary rods may be fitted with an adjustment mechanism as described for the secondary rods or both the primary rods and the secondary rods may be fitted with such adjustment mechanisms.
In this embodiment, the first threaded insert 219 and the second threaded insert 220 are threaded or tapped so as to accommodate the second grub screw 230′. In alternative embodiments, the grub screw can be a set screw or any screw suitable for adjusting the separation between the secondary rod 227 and the lower secondary rod 227″. The first threaded insert 219 and the second threaded insert 220 are formed from a material with a high thermal conductivity at the operational base temperature of the relevant thermal stage, such as brass or copper. A thermalising shim 238 is again positioned between the secondary rod 227 and the second inner secondary plate 222. This is also visible in
A thermalising shim 238 connects the secondary rods 227, 227′ to the first inner secondary plate 221, providing mechanical stability to the arrangement when the first inner secondary plate 221 is moved along the secondary rods 227, 227′. In this embodiment, the thermalising shim 238 is formed from a material having a high thermal conductivity at the operational base temperature of the relevant thermal stage, such as brass or copper, and further provides effective thermalisation of the secondary rods 227, 227′. The thermalising shim 238 is configured to thermally couple the ends of the secondary rods 227′ to the inner secondary plate 221. Advantageously, thermalisation of the secondary rods 227 and primary rods 217 at each thermal stage 201-205 reduces the time required to cool the cryogenic cooling system from room temperature to an operational base temperature. It also reduces any unwanted heat transfer between a warm end of the secondary insert and a cold end along the secondary rods 227. This is achieved by increasing the thermal conductance between the secondary rods 227 and the secondary plates, in particular where relative movement between these components is possible.
The grub screw 230 has a radial protrusion around which the thermalising shim 238 is positioned. The outer holes in the thermalising shim 238 are slotted, allowing movement of the shim perpendicular to the secondary rods 227, 227′ as indicated by the arrows. When positioned, the thermalising shim 238 is held in place between the first and second threaded inserts 219, 220 by a clamping force. The thermalising shim is also fastened securely to the first inner secondary plate 221 using shim screws 267. The thermalising shim 238 is flexible such that it maintains physical contact with the first inner secondary plate 221 and the secondary rods 227, 227′, ensuring effective thermalisation of the secondary rods 227, 227′ when the first inner secondary plate 221 is moved with respect to the secondary rods 227, 227′. This deformation of the thermalising shim 238 is visible in
In further embodiments any combination of the adjustment members previously described may be used alone or in combination.
As will be appreciated, a cryogenic cooling system is therefore provided in which a secondary insert can be demounted from the system whilst achieving effective thermalisation in a mounted position. The removal of the secondary insert allows for remote assembly, testing and set-up. Furthermore, the system has additional flexibility due to the ability to provide modular upgrades in the form of an upgraded secondary insert. The effective thermalisation, which is important for low temperature experiments, is achieved using dedicated adjustment members as described.
Number | Date | Country | Kind |
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2002787.6 | Feb 2020 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2021/050376 | 2/16/2021 | WO |