The present invention relates to an ionization cell for a mass spectrometer. In particular, the invention is applicable to mass spectrometers in which a heated electrical filament emits electrons. The invention also relates to a leak detector comprising the ionization cell.
In a mass spectrometer a gaseous sample is analyzed by bombarding the sample with a flux of electrons and then making the ionized particles thus obtained move so as to then differentiate them for example depending on their trajectory. The mass spectrometers of leak detectors thus measure and quantify a tracer gas, such as helium.
Mass spectrometers comprise for example an ionization cell containing an ionization cage and a heating electric filament that emits electrons. The molecules of the gas to be analyzed are bombarded by the electron beam and a substantial part of the molecules of the gas to be analyzed is converted into ionized particles. These ionized particles are then accelerated by an electric field. They then arrive in a zone containing a magnetic field, which has the property of altering the trajectories of the ionized particles as a function of their mass. The current of ionized particles of the tracer gas is proportional to the partial pressure of the gas in the apparatus, and its measurement allows the value of the flow rate of the detected leak to be known.
In order to make the operation of the mass spectrometer more reliable, certain ionization cells contain two filaments. A working first filament is powered to produce the electron beam and a backup second filament is intended to be powered in the event of failure of the working first filament.
However, it has been observed that the waiting time required for the backup second filament to become operational, so as to allow stable and reproducible measurement representative of the quantity of tracer gas, can prove to be excessively long (a wait of up to two hours may be necessary).
The objective of the invention is therefore to reduce the waiting time required for the ionization cell to become operational again when passing from the failed, working first filament to the backup second filament.
For this purpose, one subject of the invention is an ionization cell, for a mass spectrometer, comprising:
Specifically, the inventors have surprisingly observed that, with this arrangement of the ionization cell, the backup second filament is not altered by the operation of the working first filament.
When the failed, working first filament is switched to the backup second filament, a stable, accurate and reproducible measurement may then be rapidly obtained using the mass spectrometer immediately after the backup second filament has been sufficiently heated i.e. after about fifteen minutes of being powered. The time required to switch filament is thus significantly reduced since the backup second filament is very rapidly operational.
According to one or more features of the ionization cell, taken individually or in combination:
Another subject of the invention is a mass spectrometer leak detector comprising an ionization cell such as described above.
Other advantages and features will become clear on reading the description of the invention, and the appended drawings in which:
In these figures, identical elements have been given the same reference numbers.
The mass spectrometer 2 is connected to the inlet of a high-vacuum pump 3 the outlet of which is connected to the inlet of a roughing pump 4 via a first isolating valve 5. In this example, the gases to be analyzed 6, possibly containing the tracer gas revealing a leak, are sucked into the inlet of the high-vacuum pump 3 via a second isolating valve 7. Some of the gases to be analyzed 6 are then sampled by the mass spectrometer 2. The detector 1 may also comprise a pressure sensor 8 for determining the pressure of the gases in the piping connected to the high-vacuum pump 3, upstream of the second isolating valve 7.
More easily seen in
The ionization cell 9 comprises an ionization cage 10, in the form of a parallelepiped-shaped box, having a first entrance slit 11 for the passage of the electron beam 12. The ionization cell 9 also comprises a working first filament 13 that forms the electron beam 12 when it is powered. The working first filament 13 is placed facing the first electron entrance slit 11 of the ionization cage 10, so that a maximum number of electrons enter into the ionization cage 10.
The ionization cell 9 thus makes it possible to ionize the gases to be analyzed 6 by bombarding them with the electron beam 12, obtaining a beam 14 of ionized particles.
The ionization cage 10 also has an exit slit 15, on a side 16, for the passage of ionized particles 14a, 14b, 14c formed in the ionization cage 10. In
The deflection and selection means comprise for example a means for generating an electric field (not shown) for accelerating the ionized particles 14a, 14b, 14c and a means for generating a magnetic field (not shown), oriented substantially along the arrow B, such as permanent magnets, for deflecting the trajectory of the ionized particles 14a, 14b, 14c, with radii of curvature Ra, Rb, Rc, depending on the mass of the ionized particles.
Thus, the beam 14 of ionized particles, which contains ionized particles of different masses, divides into several beams 14a, 14b, 14c, each beam containing only ionized particles having the same m/e ratio (ratio of the atomic mass of the particle to the number of electrons lost on ionization). For example, ionized helium particles 14c are separated from the lighter ionized hydrogen particles 14b, the radius of curvature Rb of which is smaller, or from the heavier ionized nitrogen or oxygen particles 14c, the radius of curvature Rc of which is larger.
The total pressure in the chamber of the mass spectrometer 2 must be kept lower than 10−1 pascals so that the trajectories of the electrons and of the ionized particles are not disturbed by the residual molecules.
The deflection and selection means may also comprise a triode electrode 17 for collecting the ionized particles 14a the mass of which is greater than that of the tracer gas, and an aperture 18 for selecting the ionized particles 14c of tracer gas, and a retarding electrode 19 for eliminating noise caused by other ionized species.
The leak detector 2 also possesses an acquisition chain especially comprising a DC current amplifier 20 located downstream of a target 21 that receives the flux of incident ionized tracer gas particles 14c from the retarding electrode 19, so as to convert this flux into an electron current.
The ionization cell 9 furthermore comprises a backup second filament 22, intended to be powered, in the event of failure of the working first filament 13, so as to produce an electron beam instead of the working first filament 13. The backup filament 22 is placed opposite a second electron entrance slit placed on a face of the ionization cage 10 (not visible in
The ionization cell comprises means for switching the power supply, allowing one of the two filaments to be selectively powered so as to ensure operating continuity by making it possible to switch the power supply from the working first filament 13 to the backup second filament 22 if the working filament 13 fails.
In
The filaments 13, 22 are powered, on the one hand, by an electrical current allowing them to be heated to incandescence. For example the filaments 13, 22 are connected to a current supply 23a providing a power of 14 W below 3 A. On the other hand, the filaments 13, 22 are supplied with a voltage by a voltage supply 23b of between 100 V and 300 V, connected to the filaments 13, 22 so that the potential of the ionization cage 10 is higher, by at least 100 V, than the potential of each filament 13, 22 (see
The filaments 13, 22 may be made of iridium wire covered with an oxide deposit. The oxide deposit is for example a layer of yttrium oxide (Y2O3) or thorium oxide (ThO2).
Alternatively, tungsten filaments 13, 22 are used. However, tungsten filaments have a very short lifetime when used at a low pressure of about 10−1 pascal compared to yttriated iridium filaments. In addition, yttriated iridium filaments better withstand the ingress of air.
As may be seen in
The second entrance slit 26 is placed on a face of the ionization cage, outside of a frontal region F of the ionization cage 10 facing the first entrance slit 11. The frontal region F corresponds to the projection, onto the opposite face, of the area of the entrance slit 11, along the normal to the plane that contains it. Likewise, the backup second filament 22 is placed facing the second entrance slit 26, and therefore in a peripheral region separate from the frontal region F facing the first entrance slit 11.
The second entrance slit 26 is for example placed in a peripheral region defined by a perimeter P distant by at least one millimeter from and around the perimeter of the frontal region F facing the first entrance slit 11 (see for example
Thus, in operation, with the working first filament 13 powered, the backup filament 22 is not altered by the working first filament 13.
In the event of failure of the working first filament 13, it is enough to cut the power from the first filament 13 and alternatively to power the backup second filament 22. The mass spectrometer 2 is then operational as soon as the backup second filament 22 has been sufficiently heated i.e. after about fifteen minutes.
On switching from the failed, working first filament 13 to the backup second filament 22, a stable and accurate measurement may then be rapidly obtained using the mass spectrometer 2.
The time required to switch filament is thus significantly reduced because interaction between the working first filament and the backup second filament is reduced.
The location and shape of each entrance slit 11, 26 are chosen depending on the location of the deflection and selection means. In the embodiment of the mass spectrometer in
In the examples shown in
The first and the second entrance slits 11, 26 are for example placed on opposite faces 27, 28 of the ionization cage 10. There is then enough space at either end of the ionization cage 10 to arrange the filaments 13, 22 and their respective holders 25.
Thus in
In contrast, in
In this second embodiment, the first and second entrance slits 11, 26 define a plane substantially parallel to the plane defined by the side 16, of the ionization cage 10, containing the exit slit 15 for the passage of ionized particles.
According to a fourth embodiment shown in
Moreover, depending on the location of the deflection and selection means, it is possible to imagine other embodiments of the entrance slits 11, 26.
The ionization cell 9 thus makes it possible to offset the backup second filament 22 from the frontal region F in which interactions may take place, so that the waiting time necessary to switch from the failed, working first filament 13 to the backup second filament 22 is reduced.
Number | Date | Country | Kind |
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0901114 | Mar 2009 | FR | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FR2010/050407 | 3/10/2010 | WO | 00 | 9/8/2011 |