Beam Behaviour and Magnetic Field of K500 Scc

post conduct and Magnetic Field of K500 SccVinay Singh, A Dutta, A Agarwal, C Das, B Naik, Z A Naser, S Paul, U Bhunia, J Pradhan, J Debnath Variable ability Cyclotron Centre, 1/AF Bidhan Nagar, Kolkata 700064AbstractThe extraction of the smooth from the K500 Superconducting Cyclotron in Kolkata is posing a great ch entirelyenge. later on getting the internal radio beam, lots of effort was do to extract the beam and thereafter various experiments were designed and with with(p) to cognise the beam behaviour and to enquire the real reason. The deflector electrode was subprogramd in the Faraday shape direction. The deflector dig into, bore scope probe and the of import probe were used to investigate the beam behaviour by varying the first charitable premium and frame with the help of trim- gyrate no.13 operated in harmonised order. Finally magnetized survey mapping was through with(p). In this paper, all these experimental results are described in detail.INTRODUC TIONK500 SCC got its first internal beam till the extraction radius in Aug 2009 1. This was confirmed by presence of neutrons in the neutron detector. The important probe and zinc sulphide screen (bore scope) were the only diagnostics available then. After installing the deflector, numerous runs were tried that the beam couldnt be guided through it. A series of experiments were designed to get into the basis of the problem. It was then found that the magnetic cogitation was the main reason butt this. This was nevertheless confirmed by magnetic domain of a function mapping . In this paper the steps leading to this conclusion are described in detail.The electrostatic deflectorDeflector as a beam diagnostic elementIn K500 SCC there are two sets of deflector E1 and E2. The beam first encounters the deflector E1 which spans from 335 to 34. In the normal mode i.e., when the power supply is connected to it, and electric field of around 2.5 MV/m is created by applying high gear v oltage of 20kV amid the electrodes. The gap between them is 8mm.To eliminate the possibility, the beam was at all spillage through the deflector or not, the power supply was disconnected and the deflector was operated in Faraday mode i.e., as a beam diagnostic element.The deflector E1 is not a set element, but has certain amount of freedom in respect to its radial distance from the concentre of cyclotron. The doorway personate fire be change from 667 to 671 mm and the exit from 672 to 678 mm.The variation in position of deflector coupled with use of the initiative harmonic coils (to slightly alter the beam curvature) was make repeatedly to get the beam signature on the come out of the closeter electrode. still no significant beam up-to-date could be spy.Use of wire betroth at the entry and shit block at the exit of deflectorTo further investigate a wire mesh was placed at the entry of the deflector (Fig. 1) and a solid copper block at the exit (Fig. 2). This was done to ensure that any trace of beam reaching the deflector entry can be detected. And this beam if successfully passes through the deflector will be detected by the copper block. So, this time the deflector was used in the normal mode i.e., in the power supply mode.Wide range of beginning(a) harmonic magnetic field bountifulness and phase with the help of trim coil no.13 was applied. This was done to vary the beam trajectory near the extraction regulate so as to get beam signal from the entry mesh. However no significant beam ongoing could be detected. To further search this point, the deflector voltage and its orientation were changed through a series of iterative methods, but no current could be detected on the exit copper block.-emailprotectedUse of polymer sheets for Beam printingTo get a further insight, another(prenominal) attempt was made by putting polymer sheets on the inner section of the septum at three different locations one near the entry , cooperate at middle an d the last near the exit. After a atrophied amount of beam time the sheets were taken out for chemical analysis. This was done to exclude the possibility of any marks that could have arisen due to the high voltage discharge of the electrode. Only a faint beam natural depression (Fig. 3) was found on the sheet placed near the deflector and no impression was found on the other two placed further away.Beam characteristics apply probesThe beam appeared to be not reaching the deflector side, but at the same time the beam was very much available towards the main probe and bore probe, so further investigations were continued to know the off-centeredness of the beam. commentary of the ProbesThe K500 SCC has two kinds of probes- one is the main probe and other is the bore scope. The main probe is meant to ready the intensity of current, whereas the bore scope is means to fit the beam spot on a ZnS Screen.The main probe moves over the primaeval spiral line of the hill whereas the bore probe moves across another hill after entering from its corner (Fig. 4).To know whether the beam was shifting towards a particular area or not, need of a third probe was felt. For this reason the deflector was dismantled (to gain access to a port) and another probe called the deflector probe was installed (Fig. 4) along 25 azimuth.Scheme of measurementThe beam curvature is not circular but a grace one. The local radius of curvature will thus change as the beam proceeds. The curvature will be less at the centre of the hill and more at the valley. Moreover, the three probes are not symmetrically placed with rest respect to the orbit trajectory. So, any data that is taken for the purpose of analysis has to take into account the scalloping of the beam vis-a-vis the position of the 3 probes.Figure 4 Median Plane top pull in with main probe, bore probe and deflector probe.Profile of the BeamBeam visibility with all the 3 probes was measured separately. It was observed that although g ood amount of beam was available up to the extraction radius 670 mm in main probe and bore probe, but in deflector probe the beam current was falling at 650 mm without application of any external 1st harmonic field (Fig. 5).Figure 5 Beam profile on 3 probes without any external 1st harmonic.This clearly indicated that beam was shifted towards main probe and bore probe region. Attempts were made to equalize the beam current in all the 3 probes by using different combinations of 1st harmonic amplitude (up to 40 gauss) and phase (1-360). One of those several loop has been illustrated in figure 6.However, the distribution could not be equalized in all the three probes. From the shadowing of radial distribution of beam by using the said three probes, centering behaviour of the beam was quantified 2.Figure 6 Beam profile on 3 probes with 15 Gauss 1st harmonic (phase 151)MAGNETIC FIELD MAPPINGThese observations pointed out towards significant amount of soil in field and also towards the fact that this fault cannot be taken care of by the beam controlling parameters. Also the absolute phase measurement was done 3, which also pointed out towards the field imperfection. The remapping of the magnetic field was thus contemplated.The magnetic field mapping was done by a search coil. The Calibration factor of the search coil was found out by the use of two NMR probes.The search coil was installed on a zig that was free to move in the horizontal plane. At any azimuth the search coil moved from -1.24inch to 26.4 inches. The mapping was done for different excitations of main magnet coils namely alpha and beta coilsThe magnetic field mapping found that the average field near the central region was less by around 250 Gauss and the 1st harmonic amplitude was quite high 45 Gauss near the extraction region.Figure 7 1st Harmonic field amplitude versus RadiusFigure 8 Average field versus RadiusIn figure 7 and 8, the results of the magnetic field mapping is compared with that of the field mapping that was done earlier in year 2006.REMARKSThe experimental observation that pointed out towards magnetic field imperfection was verified by remapping of the magnetic field. The correction of magnetic field is before long being done.ACKNOWLEDGMENTThe authors would like to thank all persons who have contributed direct or indirectly, especially the control room personnel who have toiled through the day and the night in the endeavour towards a common goal.