The present invention provides a solution especially for the sealing of windows or basically cylindrically shaped objects of vessels or chambers in a way compatible with ultra-high vacuum (UHV) as well as high pressure requirements, capable of accommodating temperature differences including cooling to cryogenic temperatures as well as heating as is typically performed in UHV applications, thus allowing a simple, practical and cost-effective way to fabricate devices that require such a seal, such as gas scintillation radiation detectors.
Industry offers a number of standardized components to assemble tube work capable of withstanding pressures up to a few hundred bars while at the same time being compatible with the requirements of ultra-high vacuum (UHV) preparation allowing high purity standards. VCR®-type fittings are an example of such components; they are however limited to small diameter tubing. For larger diameter tubing, knife-edge type seals are sometimes used.
Double-ferrule fittings (see for example U.S. Pat. No. 4,915,427 or WO-A1-2009/023505) allow the use of tubes of outer diameters including two inches, albeit at the price of a seal less suited for ultra-high vacuum application as it is prone to virtual leaks. However, if those virtual leaks in such double ferrule fittings could be avoided, these fittings could play a valuable role as a UHV compatible face seal without requiring modification of the parts involved.
Further, no industry standard processes exist that allow providing tube assemblies with windows in a manner capable of sustaining pressure while at the same time being compatible with UHV requirements. Examples for special non-standard window designs can be found in U.S. Pat. No. 4,986,636 or U.S. Pat. No. 5,773,841.
It is the object of the present invention to provide a simple, easy-to-use UHV-tight and pressure-tight tube coupling, capable of withstanding large temperature variations, based on simple components and procedures, thus allowing several applications including fabrication of gas based radiation detection equipment for measuring scintillation with respective optical windows.
The tube coupling according to the invention comprises a tube and a tube fitting, wherein said tube fitting comprises a basically cylindrical body with a first central bore for receiving said tube, such that said tube is axially supported by a radially extending shoulder at the inner end of said first central bore, and wherein said tube is pressed with its end face against said radially extending shoulder by means for applying an axial force to said tube, whereby a gasket is provided between said end face of said tube and said radially extending shoulder at the inner end of said first central bore.
According to one embodiment of the invention, said means for applying an axial force is a gripping arrangement of the double ferrule type. Such gripping arrangements may be mounted prior to assembly by using a hydraulic or pneumatic swaging device. It is an advantage of this embodiment that standardized components can be used with little or no modifications.
According to another embodiment of the invention, said tube rests with its end face against said radially extending shoulder at the inner end of said first central bore, such that said gasket is pressed between said end face and said radially extending shoulder.
According to another embodiment of the invention, a disc-shaped object is placed between said end face of said tube and said radially extending shoulder at the inner end of said first central bore, and said gasket is arranged and pressed between said disc-shaped object and said end face of said tube, such that said tube is closed by said disc-shaped object in a vacuum-tight and pressure-tight manner.
According to another embodiment of the invention, said disc-shaped object is an optical window.
According to another embodiment of the invention, said optical window is made of one of quartz, glass, fused silica, MgF2 or sapphire.
The axial force on the gasket or window may be monitored. For example, by measuring the torque applied to a nut, which generates the axial force.
According to another embodiment of the invention, said gasket is made of a malleable material, in particular of gold, indium, lead, tin, platinum, copper, a fluoroelastomer (e.g. Viton®) or PTFE. Said gasket may have the form of a ring, wire or band.
According to another embodiment of the invention, said gasket is a composite sealing ring.
According to another embodiment of the invention a cushion of a material such as copper or indium is provided between said window and radially extending shoulder at the inner end of said first central bore.
The seal can be made between window and tube as described above, or analogously between window and radially extending shoulder, or if desired, in both locations.
According to another embodiment of the invention, said disc-shaped object is used as a termination of a chamber, an axial fixation, or a feed-through.
According to another embodiment of the invention said means for applying an axial force comprises an increase in the outer diameter of said tube, achieved by welding, gluing, clamping, brazing, or by machining said tube to such specifications.
Further, according to the invention, a vessel that can be evacuated to a desired vacuum and filled with gas to a desired pressure and/or heated or cooled to a desired temperature, is provided, whereby at least one tube coupling according to invention is arranged at said vessel as a vacuum tight and pressure tight access to said vessel.
According to one embodiment of the vessel according to the invention, a disc-shaped object is placed between said end face of said tube and said radially extending shoulder at the inner end of said first central bore, and said gasket is arranged and pressed between said disc-shaped object and said end face of said tube, such that said tube is closed by said disc-shaped object in a vacuum-tight and pressure-tight manner, whereby said disc-shaped object is an optical window, and is especially made of one of quartz, glass or sapphire.
According to another embodiment of the invention, means for receiving optical, infrared or ultraviolet radiation are placed on the side of the window opposite to said tube.
According to another embodiment of the invention, said optical radiation receiving means comprises one of a photomultiplier tube (PMT), solid state light detector, avalanche diode, multichannel plate, image intensifier, charge-coupled device or optical concentration sensor.
According to another embodiment of the invention, said vessel is filled with a gas, in particular a noble gas. Alternatively, nitrogen may be used. Especially, said vessel may be filled with a gas at cryogenic temperatures. Furthermore, said vessel may be filled with a liquid scintillator.
According to another embodiment of the invention, said vessel is filled with a noble gas such as xenon for gamma detection purposes or with a noble gas such as 4He or 3He for neutron detection purposes, or with a mixture of any of said gases, and is part of a radiation detector.
Alternatively, said vessel may be filled with a noble gas such as xenon for gamma detection purposes or with a noble gas such as argon, neon or krypton, or with a mixture of any of said gases, and is part of a radiation detector.
Furthermore, the walls of said vessel and/or the windows of said vessel may have a wave-length-shifting (WLS) material deposited thereon, or the said walls may have a WLS-coated liner, and said vessel is part of a radiation detector.
According to another embodiment of the invention, said vessel comprises a central tube, at both ends of which a tube coupling is provided, wherein a disc-shaped object is placed between said end face of said tube and said radially extending shoulder at the inner end of said first central bore, and said gasket is arranged and pressed between said disc-shaped object and said end face of said tube, such that said tube is closed by said disc-shaped object in a vacuum-tight and pressure-tight manner, whereby said disc-shaped object is an optical window, and is especially made of one of quartz, glass, fused silica, MgF2 or sapphire.
The invention now shall be explained on the basis of various embodiments and with reference to the drawings.
The tube fitting 10 is provided with a gripping arrangement, which comprises two concentrical ferrules 14 and 15 and a cap nut 13, which interacts with a respective outside thread on the body 11. The function of this double ferrule gripping arrangement is well-known in the art (see for example WO-A2-2007/087043). The tube fitting 10 of
Now, a standard tube fitting like the one shown in
While
Now, to create a UHV tight and pressure tight vessel or chamber with an optical access from opposing sides, a tube can be sealed with a window on both ends according to
It is evident, that the tube fitting 10 of
A radiation detector 25 of the kind shown in
Various modifications of the tube coupling explained above are conceivable within the scope of the invention:
The tube fittings 10 or 10a,b may be pre-mounted using a swaging device.
Furthermore, the end of the tubing may be modified in terms of shape, for example with a groove, a knife-edge or with different diameters than the rest of the tubing, or the counter-piece 12 may be modified in terms of shape, for example having a deeper bore to accommodate a thicker window or having a different ledge design to allow higher operation pressures, or being angled to accommodate windows with frustum shapes, or otherwise specially designed.
Flanges may be used in place of pipe fittings to compress the gasket.
One side (referred to as the process area) of the disc-shaped object 22 may be subject to vacuum and or pressure of gases of choice, the other side of the disc shaped object (referred to as the containment area) may be enclosed in a way so that in the event of a failure of the seal or the disc shaped object, such a failure will not affect areas outside of the containment areas. For example, should a seal fail under high-pressure, such a failure will not lead to the expulsion of gas or fragments outside the containment area.
The primary application, for which the tube coupling was developed, is gas based scintillation detectors. Such devices can consist of pressurized noble gas of high purity and windows that allow scintillation light to pass from the gas to photo sensors such as photomultiplier tubes (PMT) on the other side of such windows (see the WO-A2-2007/121876). The invention is beneficial to this application since it provides an efficient way to fabricate radiation detection modules largely out of standard low-cost off-the-shelf components. Other potential applications of the invention include the fabrication of optical concentration sensors, high pressure metal vapour lamps, and lasers.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/006678 | 9/16/2009 | WO | 00 | 6/4/2012 |