FR2997603A1 - CYCLOTRON - Google Patents

Abstract

The present invention relates to a cyclotron (1), comprising: - a winding, - a plurality of hill sectors (2) of ferromagnetic material, in the air gap of which the magnetic field generated by the winding is oriented so as to induce a trajectory of particles around the axis (X) of the cyclotron, these hill sectors being separated by valleys, the winding extending, between at least two hill sectors arranged on either side of a valley, approaching the cyclotron axis, so that along the axis (V) of this valley, the magnetic field to which the accelerating particles in the cyclotron are subjected passes a polarity of the same sign as in the hills to an inverse polarity, when the radius increases.

Description

TECHNICAL FIELD The present invention relates to cyclotrons and in particular those with superconductive electromagnets. BACKGROUND Cyclotrons are accelerators whose operating principle is now ancient. These accelerators have been the subject of numerous developments, in particular with the aim of increasing the energy of the particle beam delivered. The design of a cyclotron capable of accelerating high power beams is subject to various constraints. In particular at high energies, the gamma and neutron radiation emitted following the activation of its components must be as small as possible to facilitate its maintenance and radiation protection. In addition, the cost of design and manufacture must be compatible with the desired application. To produce beams of relatively high energy, for example greater than or equal to 500 MeV, it is known to produce superconducting cyclotrons in a so-called "separated sector" configuration. The latter, called "hill" sectors, are distributed all around the axis of the cyclotron, being separated by regions called "valleys", and each carry on either side of the air gap two superconducting windings that generate a field magnetic substantially perpendicular to the median plane in the gap. RF accelerating cavities are arranged between the sectors. The publication ECPM May, 2012 DAHALUS discloses a superconducting cyclotron of this type, dedicated to the acceleration of H2 + ions and to the production of H + ions by electronic peeling, represented in FIG. 1. The hill sectors are each made with a part of the yoke disposed radially outwardly, which serves to close the magnetic field. This part of the cylinder head contributes to the footprint significantly and increases the weight of iron used and the weight of the installation. In addition, the sectors have a top view in a rather complex shape, spiral, for reasons of focusing of the beam, which also tends to increase the size.

In addition, the magnetic field, in the central region of the cyclotron located radially away from the sectors towards the axis of the cyclotron, is opposite to that existing in the gap at the sector level and therefore not available to accelerate the particles, which requires the use of a pre-accelerator upstream to inject the particles with an input energy level compatible with the desired level output. This adds to the cost, bulk, and complexity of the installation. Finally, the input particle beam is subject to a space charge problem, which limits the intensity that can be injected into the cyclotron. In addition to these injection difficulties, there are difficulties in extracting the beam. As illustrated in FIG. 1, the beam H4 after electronic peeling undergoes several deviations in the same direction of rotation, which results in a strong angular dispersion of the beam, to the detriment of the efficiency of the accelerator, and can pose problems of activation of its components. To date, there is a need to further improve the cyclotrons, more particularly superconductors, to overcome the above drawbacks and in particular allow the realization of cyclotrons capable of accelerating particles to a high energy, for example greater than or equal to 60 MeV and with a significant intensity, for example greater than or equal to 2 mA The publication CYCLOTRON AND FFAG STUDIES USING CYCLOTRON CODES MK Craddock et al., Proceedings of Cyclotrons 2010, Larighou China, aims to determine the high limit in energy may have cyclotrons following the hill sectors by valleys where the magnetic field is the reverse, but no concrete realization is disclosed in this publication Summary The invention aims to meet the need above, and achieves it according to a first of its aspects by means of a cyclotron, comprising: a winding, a plurality of sectors hill in ferrous material omagnetic, in the air gap of which the magnetic field generated by the coil is oriented to induce a trajectory of the particles around the axis of the cyclotron, these hill sectors being separated by valleys, the winding extending between at least two hill sectors arranged on either side of a valley, approaching the axis of the cyclotron, so that along the axis of this valley, the magnetic field to which the particles in progress are subjected acceleration in the cyclotron passes from a polarity of the same sign as in the hills to an inverse polarity, when the radius increases. The cyclotron according to the invention has many advantages. First of all, the arrangement of the magnetic circuit allows, if desired, to extend the hill sections to the lower radii of the minimum winding radius towards the center of the cyclotron, to benefit from a wider radial acceleration range. particles. The use of an accelerator upstream of the cyclotron can thus be avoided, which simplifies the installation and reduces its cost. This also makes it possible to perform, if desired, a multi-injection, as detailed below, and to increase the intensity produced at output by the cyclotron. Moreover, at radii greater than the minimum radius of the winding, the magnetic field at the median plane in the valleys is reversed and becomes negative, which makes it possible to increase the vertical focusing properties allowing the acceleration of the beam up to at high energies. This contribution of the negative field along the orbits is all the stronger in the absence of the flux return yokes of cyclotrons with known separate sectors. In addition, the footprint is reduced, or, with equal footprint, it allows to further distance the path of the particles of the cyclotron axis and thus to extract them more easily, especially in the case of an extraction in separate towers. The hill sectors can be substantially straight, not spiraled, which makes it possible to gain compactness and to have more space not only for the radiofrequency accelerating cavities but also for the other components of the cyclotron. Thanks to the inversion of the magnetic field, the centers of curvature of the trajectories in the valleys are outside the machine, and the trajectory of the extracted ions is therefore much shorter. In the case of electronic peeling, in particular according to reaction 142+ 2F1, the difference in mass between H2 + and 1-1 and the inversion of the magnetic field in the valley sectors thus facilitate the extraction of the H + beam.

The invention may also allow, particularly in the case of an ion beam to be extracted in separate turns, to avoid the use of a septum and thus limit the activation problems that entails. Optionally, in such a case, no part necessary for the deflection of the extracted beam is required to pass through the median plane and the insertion of a weakly activatable shield of graphite to intercept the diverging particles is facilitated. The cyclotron preferably comprises alternating hill and valley sectors as it moves circumferentially around the cyclotron axis. However, the number of valley sectors may be less than that of hillside sectors, for example half less, which can facilitate the establishment of accelerating cavities and make it easier to manufacture superconducting windings. In the presence of valley areas, winding comprises portions that are common to a hill area and an adjacent valley area. The winding may comprise, between two sectors hills, two portions converging on the cyclotron axis, connected together at their end on the side of the cyclotron axis. These portions may deviate from the median plane as the radius relative to the cyclotron axis decreases. This makes it possible to soften the transition between the fields of inverse polarities, along the axis of a valley. The winding preferably comprises two windings arranged on either side of the median plane. Each winding, also called coil, preferably extends over a complete revolution around the axis of the cyclotron. Each winding may have outwardly concave portions, disposed between the hill sectors, and portions disposed along the radially outer periphery of the hill, concave inward sectors. The presence of portions of opposite concavities can facilitate the compensation of the thermal and mechanical stresses induced by the cooling of the winding at a superconductive temperature on the one hand, and improve the distribution of magnetic forces on the other structure. As noted above, the hill sectors may extend radially to the cyclotron axis further than the radius at which the magnetic field reverses into the valleys in order to participate in the acceleration of the low energy particles.

At least one sector hill can extend radially towards the axis of the cyclotron less far than the others. This makes it possible to have at least one recessed hill sector, giving off a space where an ion source can be arranged, this source being internal, or facilitating the injection of ions in the case of an external source.

The cyclotron can be multiple injection, especially in areas provided by the absence of hillside sector, due to the slightest extension to the cyclotron axis of certain sectors hill. This allows better use of the space within the cyclotron and to obtain a higher intensity. The invention is particularly suitable for extraction by separation of turns due to the absence of return yoke sectors, as explained above. Indeed the absence of breech back on the periphery of the hill areas allows to obtain a more intense reverse magnetic field with large rays in the valleys. Valley areas can also be used to further enhance this effect, thus playing the role of conventional return yokes by channeling the magnetic flux but by doing so in an area where this reverse field is useful to the beam dynamics, it is that is to say in the zones of the valleys where an inverted field is used, either for the vertical focusing of the beam, or to facilitate the extraction. Unlike traditional return yokes, these valley sectors therefore have a gap at least partially at the median plane to let through the accelerated beam and possibly the beam extracted. The cyclotron may include an extraction channel located between two adjacent hill sectors, including an extraction channel producing a magnetic field hump. This channel is open at the median plane between the last internal orbit and the extracted orbit. For example, it may be formed of bars of a ferromagnetic material or bars traversed by a current. The magnetic harmonic disturbance that it can possibly generate must be limited and corrected, but the residual disturbance can facilitate the extraction by inducing a slight precession of the last turns. The cyclotron may comprise a valley sector having a close portion of the median plane of air gap in the extraction zone. This makes it possible to locally increase the magnetic field along the extracted orbit. The cyclotron can in particular be of the isochronous type. The energy of the output beam is preferably greater than or equal to 60 MeV, or even 1000 or 1500 MeV.

The subject of the invention is, independently or in combination with the foregoing, a cyclotron comprising a plurality of sectors made of ferromagnetic material, including hill sectors and possibly valley sectors in which the magnetic field is opposite that of the hill sectors. at least one hill sector extending towards the cyclotron axis less than the other hill sectors to define at least one injection zone, and preferably a plurality of injection zones, these injection zones being preferably still distributed equiangularly around the axis of the cyclotron. The subject of the invention is, independently or in combination with the foregoing, a cyclotron comprising a plurality of sectors made of ferromagnetic material, including hill sectors and possibly valley sectors in which the magnetic field is opposite that of the hill sectors. the valley areas extending less far to the center of the cyclotron than the hill areas. DETAILED DESCRIPTION The invention will be better understood on reading the following detailed description, non-limiting examples of implementation thereof, and on examining the appended drawing, in which: FIG. a cyclotron according to the prior art, FIG. 2 is a diagrammatic perspective view of an example of a cyclotron according to the invention, FIG. 3 represents, in isolation, the windings of the cyclotron of FIG. 2; FIG. 4 illustrates the polarity of the magnetic fields in the example of Figures 2 and 3, Figures 5 and 6 are views respectively similar to Figures 2 and 4 of an alternative embodiment of the cyclotron, - Figure 7 shows the evolution of the magnetic field depending on the radius at different locations in the cyclotron of FIG. 2, as well as the evolution of the distance from the hill sector to the median plane, FIG. 8 represents a detail of embodiment of the cyclotron of FIG. 5 at the level of the a extraction zone, in the case of extraction with separate turns, - Figure 9 is a section of Figure 8 in the valley sector axis, and - Figure 10 shows the evolution of the magnetic field in the Fig. 8 extraction zone and in the median plane of air gap, as a function of the radius; Fig. 11 illustrates an example of multi-injection of ions 112 °; and Fig. 12 illustrates an extraction by peeling of H2. H +, in a valley. The cyclotron 1 according to the invention, represented in FIG. 2, is more particularly intended for the acceleration of H2 + ions, but the invention is not limited to a particular type of ion at the input of the accelerator or output of it. The cyclotron 1 has a so-called separate sector construction, with in this case a plurality of magnetic sectors of hill 2 and of magnetic sectors of valley 3. The sectors of hill 2 or valley 3 each define a gap, under vacuum, in which propagates the accelerated particle beam, the cyclotron generally having a symmetrical structure with respect to a median plane of air gap. The hill sectors 2 are disposed spaced from each other in the circumferential direction, leaving between them the valleys in which the valley sectors are arranged, in the air gap of which the magnetic field is of opposite orientation to that prevailing in the region. gap between the hills. The valley sectors can be interrupted at mid-width to allow to have in this space the accelerating cavities HF.

The sectors, whether hill or valley, are made of a ferromagnetic material such as iron and the magnetic field is created using a winding comprising, in the example in question, two superconducting windings 5 disposed respectively at above and below the median plane. Each of the windings 5 is contained in a cryostat and comprises turns, which extend continuously over the entire circumference of the cyclotron 1 along a path that allows a portion 6 of the coil, common to two adjacent sectors 2 and 3, to generate, when traversed by an electric current, both a portion of the magnetic gap field in the hill sector 2 and part of the magnetic gap field in the valley sector 3, these magnetic fields being of opposite polarities, as illustrated in FIG. FIG. 4. In the example considered, each common portion 6 deviates, close to the X axis of the cyclotron, from the median plane; this orientation of the common portions 6 makes it possible to reduce the magnetic field in the valley sectors approaching the center of the cyclotron, which makes it possible to obtain a progressive increase in absolute value of the intensity of the magnetic field when the radius increases; this also facilitates the introduction into the space provided between two adjacent hill sectors 2, of an accelerating cavity HF, of which only one of them, bearing the reference 8, has been represented in FIG. clarity of the drawing. These accelerating cavities are known in themselves and may be of the "mono gap" or "double gap" type, for example as described in the publication M.Bopp et al. The configuration of the cyclotron can facilitate the attachment of the windings 5 at the portions 12 of the windings located at the lowest radii in the region. machine, at the end of two consecutive portions 6, these portions 12 of the windings 5 may exceed sectors 2 upwards or downwards. The cyclotron 1 may comprise between 2 and n HF accelerating cavities for a machine of n magnetic periods. The number of hill sectors is between 3 and n. The number of valley sectors can be equal to the number of hillside areas, or less. There may be no valleys, since the contribution of the windings 5 to the magnetic field in this zone of the valleys is negative. Valley areas, however, have the advantage, when present, of increasing the intensity of the field in this area. FIG. 7 shows an example of a hill sector profile in the axis of the latter. It can be seen that the distance from the hill sector to the median plane varies according to the radius so as to adequately grow the field in the gap. The magnetic field is also represented in the mid-plane of air gap in the axis of a hill sector and in the axis V of a valley. The evolution of the profile of the hill and valley sectors is chosen so that the resulting magnetic field is suitable for particle acceleration. We see that in the example considered, just over 4 m from the X axis, the field in the axis of a valley is gradually reversed. The evolution of the distance to the median plane as a function of the radius of the hill sector depends on the evolution of the distance to the median plane of the winding 5 as a function of the radius.

The distance to the median plane of the hill sector 2, starting from the center, can for example decrease, pass through a first relative minimum, grow, pass through a first relative maximum, then decrease, reach a second relative minimum, then grow again.

In the example of FIG. 5, unlike the example of FIG. 2, each winding 5 extends further towards the X axis of the cyclotron. For the example of FIG. 2 as well as that of FIG. 5, the presence in the central region of the cyclotron of a positive polarity field makes it usable for accelerating the particle beam. The accelerator then makes it possible to benefit from a wide range of diameter variation to effect the acceleration. This can notably avoid having to accelerate the particles before injecting them into the cyclotron, unlike the known solution, represented in FIG. 1. The injection of the particles to be accelerated in a cyclotron according to the invention can be carried out various ways. It may be interesting that at least one of the hill sectors does not extend as far as the others towards the X axis, so as to provide space for an injector or an internal source. It is preferable to perform a multi-injection, with injection points equidistantly angularly around the X axis of the cyclotron and for example not to extend in the direction of the X axis a hill sector on two so as to spare spaces each of which can accommodate an injector or an internal source. Under these conditions, the cyclotron can simultaneously accelerate several injected beams in these locations, which can allow to gain in intensity given the space charge problems at the injection. Figure 11 illustrates an example of multi-injection. Each winding 5 has its own cryostat or both windings 5 are housed in the same cryostat. A cryostat keeps the superconducting material at a superconducting temperature. This material is, in known manner, in contact with a copper soleplate which drives the electric current at the output of the superconducting state. In the peripheral region of the cyclotron, at the portions 13 of the windings 5 of the hill 2 sectors, the cryostats of the upper and lower windings can meet, which may lead to having only one cryostat. The extraction of the particles of a cyclotron according to the invention can be carried out in various ways.

A first extraction technique is to use an electronic peeler, which can be useful for example when the accelerated particles are H2 ÷ ions. When the electronic peeler passes, the H2 + ions can be converted into H + ions which, because of their lower mass, follow a different curvature trajectory in the magnetic field, as illustrated in FIG. 12. The peeler can be placed at the exit of a sector hill so that the beam F1 is deflected outwardly of the cyclotron and then channeled appropriately out of the cyclotron. The cyclotron according to the invention may also be suitable for a so-called extraction with separate turns, so that two consecutive trajectories are radially offset sufficiently to allow the deflection of the beam on its last turn. To do this, it may be advantageous to have, as illustrated in FIGS. 8 and 9, a radially inner side of the valley sector used for extraction, a set of bars 15, 16 made of ferromagnetic material, including two wider bars 15, which create between them an extraction channel, these bars 15 being preceded by approaching the X axis of a series of disturbing bars 16 of harmonic correction, arranged to give the magnetic field the desired profile. Such an arrangement makes it possible to create a hump of the inverse magnetic field to give curvature to the extracted beam, contrary to the classical case where the magnetic field is not reversed in which a magnetic field dip or a radial electric field should be created. introducing parts in the median plane between the extracted beam and the last internal orbit to create the curvature of the extracted beam. The illustrated solution is a passive channel solution, but solutions with active channel elements could be implemented. FIG. 10 shows the result of a simulation of the magnetic field in the median plane as a function of the distance to the X axis, revealing the local perturbation induced by the presence of the busbar 15 and 16 of FIG. 9. In the extraction zone, the valley sector 3 may have a recess 20 towards the median plane, so as to form a close part allowing to locally increase the intensity of the reverse magnetic field, and thus to further bend the trajectory of the particles to facilitate their exit. Of course, the invention is not limited to the examples of cyclotrons which have just been described.

Although the invention is particularly applicable to superconducting cyclotrons, the invention may nonetheless find an interest in non-superconducting cyclotrons. The invention is not limited to the acceleration of ions of type H + or H2 + and applies to the acceleration of other ions, in particular heavier ions with extraction by modification of the state of charge. The cyclotron-accelerated particles according to the invention can be used in many applications, for example the production of radioactive isotopes by directing the beam towards a target or to feed an accelerator-controlled sub-critical nuclear reactor. , says "ADS". The phrase "with one" should be understood as being synonymous with "having at least one".

Claims (17)

REVENDICATIONS1. Cyclotron (1), comprising - a winding, - a plurality of hill sectors (2) of ferromagnetic material, in the air gap of which the magnetic field generated by the winding is oriented so as to induce a trajectory of the particles around the axis (X) of the cyclotron, these hill sectors being separated by valleys, the winding extending between at least two hill sectors arranged on either side of a valley, approaching the axis of the cyclotron, so that along the axis (V) of this valley, the magnetic field to which the accelerating particles in the cyclotron are subjected passes from a polarity of the same sign as in the hills to an inverse polarity, when the radius increases. 2. Cyclotron according to claim 1, comprising valley sectors (3) of ferromagnetic material disposed where the magnetic field is of the reverse orientation of that prevailing in the air gap sectors hill. 3. Cyclotron according to claim 2, the magnetic fields in a sector hill and in a sector valley consecutive being generated at least partially 20 by a portion (6) winding common to these sectors (2, 3). 4. Cyclotron according to one of claims 2 and 3, comprising alternating sectors of hill (2) and valley sectors (3) when moving circumferentially around the axis (X) of the cyclotron. 5. Cyclotron according to any one of claims 2 to 4, the number of sectors 25 valley (3) being less than that of sectors hill (2). 6. Cyclotron according to any one of claims 2 to 5, the hill sectors (2) extending radially towards the axis (X) of the cyclotron further than the radius at which the magnetic field is reversed in the valleys. Cyclotron according to any one of the preceding claims, the coil being superconducting. 8. Cyclotron according to any one of the preceding claims, 1 coil extending over a complete revolution about the axis (X) of the cyclotron. 9. Cyclotron according to any one of the preceding claims, the coil comprising between two hill sectors (2) at least one portion (6) extending away from the median plane, when approaching the axis. (X) cyclotron. 10. Cyclotron according to any one of the preceding claims, at least one hill sector (2) extending radially towards the axis (X) of the cyclotron less far than the others. 11. Cyclotron according to any one of the preceding claims, being multiple injection, especially in areas provided by the absence of hill sector (2), due to the slightest extension to the axis (X) of the cyclotron of some hillside areas. Cyclotron according to any one of the preceding claims, being at injection of 1-12 ± and formation of fuc. by electronic peeling or injection of fr and extraction of 11 by separation of turns. 13. Cyclotron according to any one of the preceding claims, comprising an extraction channel located between two adjacent hill sectors (2), in particular an extraction channel formed between two bars (15) of a ferromagnetic material or traversed by a current, these two bars being arranged in particular between the two sectors hill (2). Cyclotron according to any one of the preceding claims, comprising a magnetic sector arranged in a valley where the magnetic field is the opposite of that prevailing in the air gap of the hill sectors, having a part (20) close to the median plane of gap, in an extraction zone. 15. Cyclotron according to any one of the preceding claims, comprising a graphite screen disposed in the air gap. 16. Cyclotron (1) comprising - a plurality of sectors of ferromagnetic material, including hills (2) and possibly valley sectors (3) where the magnetic field is the reverse of that of the hill sectors, at least one sector hill (2). ) extending towards the axis (X) of the cyclotron less than the other hill sectors to define at least one injection zone, and preferably a plurality of injection zones, these injection zones being preferably evenly distributed equiangularly around the axis (X) of the cyclotron. 17. A cyclotron comprising a plurality of sectors of ferromagnetic material, including hill sectors (2) and valley sectors (3) where the magnetic field is the inverse of that of the hill sectors, at least one valley sector (3) having a setback (20). ) towards the median plane in a beam extraction zone, bars (15, 16) disturbing the magnetic field preferably being disposed between the two hill sectors (2) adjacent to said valley sector (3).