Beyond the Intelligent-shell Concept: the Clean-mode-control for Tearing Perturbations

Zanca, P.

doi:10.1585/pfr.5.017

Cited by 4 publications

(14 citation statements)

References 20 publications

(49 reference statements)

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“…In fact CMC operations at high currents are characterized by transient quasi-singlehelicity (QSH) conditions, where the innermost resonant TM grows at the expense of the others [10]. The experimental results have stimulated the development of a MHD model able to simulate the evolution of TM phases and edge amplitudes under CMC action [11,12]. The closed-loop system formed by the single-fluid motion equation, and the equations describing the TM radial field diffusion across the shell(s), the electro-technical modelling of the coils, the acquisition system of measurements and the CMC feedback law is solved using a semianalytical approach.…”

Section: Introductionmentioning

confidence: 99%

“…In this case, the self-consistent inclusion of evolution of TM amplitudes at the resonant surfaces would require a simulation of the dynamo mechanism, which is beyond the possibility of the model. The model can deal with a multiple shell layout, but in [11,12] a single shell, acting as a vacuum vessel, has been taken in order to simplify the parametric analysis discussed therein. Moreover, coils have been located outside the vacuum vessel, as in the present RFP experiments, while sensors have been placed inside it.…”

Section: Introductionmentioning

confidence: 99%

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Feedback control of dynamo tearing modes in a reversed field pinch: comparison between out-vessel and in-vessel active coils

Zanca

2010

Plasma Phys. Control. Fusion

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In the framework of innovative feedback schemes for control of dynamo tearing modes (TMs) in reversed field pinch (RFP) devices, the possibility of placing active coils between a non-conducting first wall and the vacuum vessel is investigated with a MHD based model. In this formulation the vacuum vessel plays the role of a stabilizing shell. With active coils placed outside the vacuum vessel and magnetic sensors located inside it, a previous study (Zanca 2009 Plasma Phys. Control. Fusion 51 015006) has shown that the ratio between the TM radial field amplitudes at the sensors' radius and at the resonant surface can be made close to but not smaller than the ideal-shell limit. This analysis considered a continuous-time modelling of the feedback. The same model admits a very appealing solution when applied to the in-vessel coil configuration: for high gains the radial field measured by sensors located between the first wall and the coils is reduced virtually to zero and the TM rotation frequency approaches the unperturbed natural value. In this case the feedback would mimic the stabilizing action of an ideal shell placed at the sensor radius. An improvement which makes the model closer to a realistic digital feedback is also presented. This is realized by introducing a discretetime feedback action which includes a non-zero latency time. Unfortunately, the nice solution for in-vessel coils becomes unstable for realistic TM amplitudes when passing to the discrete-time feedback. In contrast the feedback of outvessel coils is robust to time discretization, except when the vacuum vessel time constant becomes very small. This analysis indicates that future RFPs should rely on feedback systems of out-vessel coils.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Feedback control of dynamo tearing modes in a reversed field pinch: comparison between out-vessel and in-vessel active coils

Zanca

2010

Plasma Phys. Control. Fusion

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“…The minimum of ζ m,n is as much closer to the ideal-shell limit, i.e. the value with an ideal shell in the place of the resistive one, as smaller is the ratio between the delay of the feedback and the shell time constant, at least in the limit of relatively thin shell (see figure 5 of [46]). Therefore, the ultimate CMC possibilities are fixed by the plasma-shell proximity.…”

Section: Cmc Limits In Dynamo Mode Controlmentioning

confidence: 79%

“…The analysis [17,46] illustrated this, adopting the simplifications of a single shell placed at a finite distance from the plasma, and a continuous-time feedback, with the delays of acquisition and coils' amplifiers modeled by one-pole filter laws. The minimum of ζ m,n is as much closer to the ideal-shell limit, i.e.…”

Section: Cmc Limits In Dynamo Mode Controlmentioning

confidence: 99%

Advanced feedback control of magnetohydrodynamic instabilities: comparison of compensation techniques for radial sensors

Zanca¹,

Marchiori²,

Marrelli³

et al. 2012

Plasma Phys. Control. Fusion

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A survey of the feedback algorithms exploiting radial sensors applied in RFX-mod is presented. A Fourier variant of the 'intelligent shell', whose efficiency is limited by the aliasing coming from the active coils' sideband harmonics, and 'clean mode control', a method to single out and cancel this pollution, are compared for both tearing mode and resistive wall mode control. Simulations for 'explicit mode control', a different technique still to be tested in RFX-mod, are also discussed: this method removes the sidebands' effect by subtracting the entire vacuum coils' field. The conclusion is that 'clean mode control' is a better way to implement radial sensors. Since the latter have the technical advantage of allowing an arrangement outside the plasma-facing structures, the efficient control scheme developed at RFX-mod can be considered reactor-relevant.

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“…In particular, the feedback does not modify the amplitude rampup curve, but changes significantly the rampdown curve making possible the return of the spontaneous rotation with a modest amplitude decrease. This behavior is due to the fact that the feedback mimics a quasiideal boundary at the plasmafacing conducting structure radius [86], thus low ering the phase delay between eddy currents in the vacuum vessel and TM current at the resonant surface. Therefore, for a given tearing mode amplitude, the braking torque between the vacuum vessel and the tearing mode is much lower when feedback is acting, leading to the higher unlocking threshold compared to the nonfeedback case.…”

Section: Threshold For Tearing Modes Unlockingmentioning

confidence: 99%

Upgrades of the RFX-mod reversed field pinch and expected scenario improvements

Marrelli¹,

Cavazzana²,

Bonfiglio³

et al. 2019

Nucl. Fusion

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RFXmod is a Reversed Field Pinch device that allowed performing experiments in regimes with a plasma current up to 2 MA, thanks to its MHD active control system. Experiments have shown that improved plasma performances are obtained when in the resonant part of the m = 1 spectrum one dominant tearing mode is much higher than the other secondary ones (quasi single helicity states). Tearing modes play a crucial role in determining energy and particle transport. Based on the present understanding of the interplay between passive conductive boundaries and tearing modes in an RFP, an upgrade of RFXmod machine assembly has been designed, dubbed RFXmod2, and it is now being implemented. The highly resistive Inconel vessel will be removed, graphite tiles will be attached to the copper stabilizing shell and the stainless steel support structure will be modified in order to be vacuum tight. In RFXmod2, the shellplasma proximity decreases from b/a = 1.11 to b/a = 1.04 and copper, instead of Inconel, will be the continuous conducting structure nearest to the plasma. MHD nonlinear simulations show that secondary tearing modes amplitude and the edge bulging due to their phase locking will decrease; moreover the plasma current threshold for tearing modes wall locking will also significantly increase.

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Beyond the Intelligent-shell Concept: the Clean-mode-control for Tearing Perturbations

Cited by 4 publications

References 20 publications

Feedback control of dynamo tearing modes in a reversed field pinch: comparison between out-vessel and in-vessel active coils

Feedback control of dynamo tearing modes in a reversed field pinch: comparison between out-vessel and in-vessel active coils

Advanced feedback control of magnetohydrodynamic instabilities: comparison of compensation techniques for radial sensors

Upgrades of the RFX-mod reversed field pinch and expected scenario improvements

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