This is a §371 of International Application No. PCT/EP2007/003958, with an international filing date of May 4, 2007 (WO 2008/135064 A1, published Nov. 13, 2008).
The disclosure relates to a collector sweeping method, in particular for controlling an electron beam in a beam collector of a vacuum device, like a vacuum tube of a microwave generator. Furthermore, the disclosure relates to a method of microwave generation with a microwave generator including collector sweeping of an electron beam. Furthermore, the disclosure relates to a collector sweeping apparatus and a microwave generator being adapted for implementing the above methods.
The generation of microwaves using electron tubes, in particular using a free electron maser, gyrotron or klystron, is generally known. As an example, a gyrotron includes an electron source for generating a hollow beam of highly accelerated electrons and a cryomagnet resonance device for forcing the electrons into a cyclotron motion, wherein the microwave is emitted. A beam collector is provided for collecting the electron beam after separation of the microwave with a microwave optic. The beam collector is adapted not only for absorbing the electric current represented by the electron beam, but rather for dissipating waste power, which has been kept in the electron beam after the microwave emission.
Heat dissipation in beam collectors represents a serious problem in particular with high power microwave generators. As an example, high power millimeter wave vacuum tubes operate with a radio frequency (rf) power of typically 1 MW in cw-mode with an efficiency of 30% to 50%. In this range of efficiencies, typically 1 to 2 MW power remains in the electron beam after the microwave generation. This remaining power must be dissipated as waste power in the beam collector. The beam collector typically is made from copper with a cylindrical shape. Electrons are guided by an axis symmetric strong stationary magnetic field (typically 5-6 T) through an entrance area into the axis-symmetric collector. The diverging magnetic field lines and thus the drifting electrons intersect at some vertical position with the collector wall. The intersection area (strike area) forms a horizontal ring with a typical power density of e.g. 20 MW/m2. Although copper as excellent cooling properties and a sophisticated water-cooling system is integrated into the beam collector wall, this power density is far beyond existing cooling technology. With a continuous operation, this power density would lead to melting of the beam collector.
For avoiding damage to the beam collector, available gyrotrons are adapted for a collector sweeping technique (magnetic field sweeping technique, see e.g. S. Alberti et al. “European high-power CW gyrotron development for ECRH systems” in “Fusion Engineering and Design” vol. 53, 2001, p. 387-397). Generally, collector sweeping comprises superimposing the stationary diverging magnetic field with a magnetic sweeping field, which sweeps (continuously moves, deflects) the hollow electron beam over the inner wall of the beam collector to reduce the local power density in a time average (
In particular,
According to
The VFSS has a general disadvantage in terms of low electrical efficiency. The copper wall of the beam collector 230′ represents a single turn, short-circuited coil efficiently shielding the vertical sweeping field. Powerful AC-power supplies in connection with large, water cooled sweep coils are required to provide the necessary sweeping capability. This disadvantage can be avoided with the conventional collector sweeping method illustrated in
With TFSS, collector sweeping is provided by transversal sweeping coils 11′. In this case, a transversal sweeping field is created adding a rotating horizontal vector component to the diverging magnetic field. With the transversal sweeping field, the intersection area of the electron beam 1′ is a rotating ellipse. As a small distortion perpendicular to the z-direction is enough for an efficient deflection of the electron beam, the transversal sweeping coils 11′ can be positioned in front of an entrance area of the beam collector 230′ so that the above shielding problem of the VFSS technique is significantly reduced. Furthermore, this section of the gyrotron is built from stainless steel rather than copper with reduced conductivity.
A general problem of both VFSS and TFSS techniques is related to the so-called power peaking during the sweeping period.
Generally, there is an interest to reduce the power peaking not only in gyrotron beam collectors, but rather in any beam collector of a high-power vacuum device, as it is applied e.g. in other microwave generators, in particular for the purpose of heating a plasma in a fusion reactor.
It could therefore be helpful to provide improved collector sweeping methods and apparatuses for controlling an electron beam in a beam collector avoiding the disadvantages and restrictions of the conventional techniques.
According to a first aspect, the present disclosure is based on the general technical teaching of providing a collector sweeping method for controlling an electron beam in a beam collector, wherein a transversal sweeping field is modulated for a continuous variation of a position and/or orientation of the sweeping electron beam in the beam collector. According to a second aspect, the present disclosure is based on the general technical teaching of providing a collector sweeping apparatus adapted for controlling an electron beam in a beam collector, wherein a transversal sweeping coil device of the collector sweeping apparatus is provided with a modulating device being arranged for a position and/or orientation modulation of the transversal sweeping field. Further independent aspects comprise a method of microwave generation and a microwave generator including the collector sweeping technique.
According to the disclosure, the transversal sweeping field is modulated. The transversal sweeping field is a rotating magnetic field having at least one vector component perpendicular to a longitudinal direction of the beam collector. The transversal sweeping field deflects the electron beam such that a tilted, rotating intersection area is formed in the beam collector. Advantageously, the modulation of the transversal sweeping field results in a continuous variation of the longitudinal (in particular axial) position and a tilting angle of the intersection area. Accordingly, the pronounced power deposition maxima (power peaking) occurring with the conventional technique can be avoided, and a homogenous distribution of waste power is obtained. With the modulation, the heating profile along the longitudinal direction of the beam collector is broadened, so that the power peaking is reduced. In particular, the power density at the turning point of the intersection area near the entrance area of the beam collector (proximate or lower turning point) is essentially reduced as the proximate turning point is repeatedly (such as periodically) moved due to the modulation of the transversal sweeping field.
As an advantage, a collector sweeping system, which generates a homogenous power distribution along the whole heating profile is provided for the first time. The disclosed collector sweeping has particular advantages for vacuum tubes being adapted for generating a microwave output power above 1 MW, in particular above 2 MW. However, the disclosed collector sweeping also has advantages for the conventional rf-tubes, because they can be designed more economically (in particular with smaller collectors) or operated with higher safety margin and/or extended lifetime.
According to a first example, the transversal sweeping field is modulated by superimposing the transversal sweeping field with a vertical sweeping field. Advantageously, the intersection area, e.g. the intersection ellipse in a cylindrical beam collector, is shifted up and down (or forward and backward), so that the peaks of the power deposition profile along the longitudinal extension of the beam collector are smoothed out. As a particular advantage, available hardware can be used for providing an exemplar collector sweeping. In particular, available vertical field coil devices can be combined with a transversal field coil device for generating the modulated transversal sweeping field.
The first example has a particular advantage in terms of reducing power peaking without generating new “hot spots”. The modulation of the transversal sweeping field with the vertical sweeping field yields not only a shifting of power peaking but rather real attenuation. Due to the frequency dependent contributions of the thick collector wall (skin effect), the superposition of transversal and vertical sweeping fields is a non-linear process. Therefore, in consideration of the complex interaction of superimposed divergent time dependent fields in presence of shielding and deformation effects by the collector wall, in particular copper wall, the power peaking attenuation represents a surprising and advantageous result.
According to a second example, the transversal sweeping field is subjected to an amplitude modulation. In this case, the tilting angle of the rotating intersection area is modulated, so that the power peaks of the power density profile are smoothed out. The second example has the additional advantage of technical simplicity. A vertical field coil system is not required for implementing the amplitude modulation of the transversal sweeping field.
According to a further example, the transversal sweeping field can be modulated with both of the vertical sweeping field according to the above first example and the amplitude modulation according to the above second example. Advantageously, this combination allows a further improvement of the power density profile within the beam collector.
For implementing these examples, the collector sweeping apparatus of the disclosure comprises a vertical field coil device being arranged for superimposing the transversal sweeping field with the vertical sweeping field, and/or an amplitude modulation device being connected with the transversal sweeping coil device for subjecting the transversal sweeping field to an amplitude modulation.
Further advantages are obtained if the transversal sweeping and the modulation of the transversal sweeping field are effected on different time scales. For example, a transversal sweep frequency, which typically is the rotation frequency of the transversal sweeping field, is larger than the vertical sweep frequency of the modulating vertical sweeping field and/or the amplitude modulation frequency. With this example, the power deposition profiles are smoothed out by a slow vertical displacement and/or tilting of the intersection area. According to certain variants, the intersection area of the electron beam rotates at least 2 times, particularly preferred at least 5 times until one vertical cycle (first embodiment) or tilting cycle (second embodiment) is completed. In other words, the ratio of the transversal sweep frequency and the vertical sweep frequency (or amplitude modulation frequency) is preferably larger than 2, particularly preferred larger than 5.
Further advantages with the above second example are obtained, if the amplitude modulation has a modulation depth smaller than 70%, in particular equal or smaller than 50%. With these parameters, homogenous power deposition profiles have been further optimized.
Typically, the vertical sweeping field modulating the transversal sweeping field (first example) can be generated with a vertical field coil device extending along the longitudinal direction of the beam collector, possibly even around the entrance area thereof. In this case, improved smoothing of the power peaking distant from the entrance area can be obtained. However, according to a particular advantage, the vertical field coil device is be restricted to a vertical field coil (so-called entrance area coil) arranged at the entrance area of the beam collector. The inventors have found that generating the vertical sweeping field for modulating the transversal sweeping field exclusively by the entrance area coil is suitable for smoothing the proximate power peaking. With the provision of the entrance area coil only, the structure of the collector sweeping device is essentially simplified. The disadvantages of low efficiency of the conventional VFSS technique are avoided.
A further advantage of the collector sweeping technique is given by the capability of using various arrangements of transversal field coils selected in dependence on the particular application. For example, at least two transversal field coils are arranged just before the entrance area of the beam collector. Only two transversal field coils are enough for providing a switching transversal sweeping field, which is modulated with the vertical sweeping field and/or amplitude modulation. Preferably, an arrangement of three or six transversal field coils is provided resulting in advantages in terms of field uniformity. According to a particular example, three pairs of transversal field coils are arranged with a relative displacement of 120°. With a pair-wise excitation of the coils, a rotating magnetic field for transversal sweeping is obtained.
Another advantage of the improved operation safety of the disclosed collector sweeping is given by the fact that there are no particular requirements as to a control of the sweeping fields. Parameters of transversal and vertical sweeping, in particular transversal sweep frequency, vertical sweep frequency, amplitude modulation frequency, vertical sweep amplitude, shape of amplitude modulation and/or modulation depth, can be adjusted in dependence on the features of the beam collector, in particular cooling capacity, dimensions, and the operation conditions, like e.g. electrical current of the electron beam. However, according to a modified example, a feedback control of at least one of the transversal and vertical sweeping fields can be implemented. With this variant, the collector sweeping method includes a step of temperature detection for obtaining a temperature distribution in the beam collector and a further step of controlling at least one of the transversal sweeping field and the modulation of the transversal sweeping field in dependence on the detected temperature distribution. For collecting temperature data, a plurality of thermoelectric sensors may be used.
Further details and advantages are described in the following with reference to attached drawings, which show in:
With the following description of exemplary embodiments, reference is made to an application of the disclosed collector sweeping for controlling an electron beam in a high power gyrotron. It is emphasized that the application is not restricted to gyrotrons, but rather possible with other vacuum devices including a beam collector for collecting an electron beam, like e.g. other vacuum devices with magnetic field guided electron beam dumps with high power density like e.g. Free Electron Masers (FEM) or Free electron Lasers (FEL). Furthermore, exemplary reference is made to the application with a cylindrical beam collector, wherein the electron beam is periodically swept along the longitudinal extension of the inner wall of the beam collector. The disclosed collector sweeping can be implemented with a different beam collector design in an analogue way. As an example, the inner wall of the collector can be adapted for a glancing incidence of the electron beam on a funnel-shaped collector wall. With the following examples, a periodically rotating transversal sweeping field having a predetermined transversal sweep frequency is assumed. The disclosure can be implemented with a non-uniform rotation or a stepwise changing of the direction of the transversal sweeping field in an analogue way.
The longitudinal direction of electron transport in the microwave generator 200, in particular into the beam collector 230 and the axial direction of the beam collector is referred to as z-direction. The radial directions (x- and y-directions) are oriented perpendicular relative to the z-direction.
The collector sweeping apparatus 100 is arranged at the entrance side of the beam collector 230, e.g. at an axial position between the cryomagnet resonance device 220 and the beam collector 230, in particular directly before the entrance area 231. Depending on the example, the collector sweeping apparatus 100 comprises a combination of a transversal sweeping coil device 10 with a vertical sweeping coil device 20 (first example) or exclusively the transversal sweeping coil device 10 (in combination with an amplitude modulation device 30, second example), or a combination of a transversal sweeping coil device 10 with both of the vertical sweeping coil device 20 and the amplitude modulation device 30.
The transversal sweeping coil device 10 comprises e.g. six transversal sweeping coils 11 to 16.
The vertical sweeping coil device 20 comprises a cylindrical vertical sweeping coil 21 connected with a vertical sweeping power supply 22. The coil 21 is arranged with axis-symmetry around the path of the electron beam 1 just before the entrance area 231 of the beam collector 230. As an aspect of this example, the axial length of the vertical sweeping coil 21 can be selected essentially shorter compared with the conventional VFSS-coil. As an example, the vertical sweeping coil 21 may comprise a few turns, e.g. below 10 turns or even one turn only. Accordingly, the power consumption and the costs of the vertical sweeping coil can be essentially reduced. The vertical sweeping coil power supply 22 comprises an AC power supply adapted for providing an AC current for exciting the vertical sweeping coil 21. The AC current is selected in dependence on the coil design and the magnitude of the stationary magnetic field.
The amplitude modulation device 30, which may be integrated into the transversal sweep power supply 17, is schematically illustrated
As an exemplary operation mode, the coil currents in both transversal and vertical sweeping field devices can be adjusted with supplies 17, 22 to maintain the same overall beam spreading, i.e. with increasing transversal sweeping field amplitude, the vertical sweeping field amplitude is reduced.
While the transversal sweeping coil device 10 creates an elliptic intersection area of the sweeping electron beam as with the prior art technique (see
According to
The features disclosed in the above description, the drawings and the claims can be of significance both individually as well as in combination for the realization of the aspects disclosed and its various forms.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2007/003958 | 5/4/2007 | WO | 00 | 11/24/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/135064 | 11/13/2008 | WO | A |
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