RuPAC2016 - List of Authors (Feschenko, A.)

Paper	Title	Page
THXSH01	Development of the INR Linear Accelerator DTL RF System	191
	A.I. Kvasha, V.L. Serov RAS/INR, Moscow, Russia A. Feschenko MIPT, Dolgoprudniy, Moscow Region, Russia
	The regular INR DTL RF system operation began in 1992. By this point three new type of vacuum tube, designed purposely for INR linear accelerator, were manufactured at OKB "Swetlana" in the amount sufficient for RF system operation during 20 years. Among them were two vacuum tubes for final RF power amplifier - GI-54A and RF driver - GI-51A and also vacuum tube for powerful anode modulator - GMI-44A. In the late 80s manufacture of these vacuum tubes was stopped and since 1990 designing of new vacuum tube for RF output power amplifier instead of GI-54A was started. The new vacuum tube GI-71A with output RF power up to 3 MW in pulse, plate power dissipation up to 120 kW and power gain about 10 was simpler and less expensive in comparison with GI-54A. The transition to new vacuum tube began in 1999 and finished in 2014. Successful testing of GI-57A as RF driver, fulfilled in 2008, opened the possibility of replacement GI-51A. As for GMI-44A replacement there are no analogues, produced in Russian federation, and, as it turned out, the only option was GI-71A again. Below some problems, connected with the vacuum tubes replacement, as well as main results of twenty years DTL RF system operation are considered.
	Slides THXSH01 [4.748 MB]
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TUZMH02	INR High Intensity Proton Linac. Status and Prospects.	48
	A. Feschenko, L.V. Kravchuk, V.L. Serov RAS/INR, Moscow, Russia
	The status and the prospects of High Intensity INR Linac are presented. The routine beam intensity is equal to 130 mkA. The annual accelerator run duration is about 1600 hours. The main beam user facilities are multipurpose complex for neutron science, isotope production facility and proton therapy facility. The primary activities are accelerator maintenance, modernization of accelerator systems and beam transportation channels, increasing of accelerator reliability, improvement of beam parameters.
	Slides TUZMH02 [7.267 MB]
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THCBSH01	INR RAS Instrumentation for Bunch Shape and Beam Cross-Section Monitoring	204
	S.A. Gavrilov, A. Feschenko, P.I. Reinhardt-Nickoulin RAS/INR, Moscow, Russia
	Instruments for bunch shape and beam cross-section diagnostics at ion linacs are as important as complicated devices. Widespread Bunch Shape Monitors developed in INR RAS are used during a linac commissioning and optimization of beam dynamics. Beam Cross-Section Monitors implemented at INR RAS linac provide efficient non-destructive beam tuning and control. Features of both monitors investigated in simulations and beam tests are described. A variety of experimental results are presented.
	Slides THCBSH01 [12.054 MB]
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TUPSA004	Proposal of the Accelerating Structure for the First Cavity of the Main Part of INR Linac	216
	I.V. Rybakov, A. Feschenko, Y.Z. Kalinin, L.V. Kravchuk, V.N. Leontiev, A.N. Naboka, V.V. Paramonov, V.L. Serov RAS/INR, Moscow, Russia
	For the beam intensity and overall stability improvement of INR linac replacement of the first four section cavity of the main part is required. The present cavity is realized as the Disks and Washers (DAW) structure. The new cavity should not lose to the present one in electro dynamical parameters with minimal modifications in the rest linac systems. As the possible structures for the first cavity replacement both proven in exploitation structures and promising developments were considered. The analysis of electro dynamical parameters, coupled RF heating, mechanical processes and manufacturing analysis were performed for the considered structures. For further development the Cut Disk Structure (CDS) option is proposed as the structure with satisfying RF parameters and having the smallest transverse dimensions in comparison with analogues. For the production simplification with minimal losses in electro dynamical parameters an unification of the main geometrical parameters for the four sections cells was performed. The possibility of multipaction in the cavity is considered and an option for its damping is proposed. The manufacturing tolerances for the structure are estimated.
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THPSC055	Electrodynamic Characteristics of RF-Deflector for Bunch Shape Monitor	659
	D.A. Chermoshentsev, A. Feschenko, S.A. Gavrilov RAS/INR, Moscow, Russia D.A. Chermoshentsev MIPT, Dolgoprudniy, Moscow Region, Russia D.A. Chermoshentsev Skoltech, Moscow, Russia
	Bunch shape monitors, based on a transverse RF-scanning of secondary electrons, are used for measurements of particles longitudinal distribution in bunches at different linear ion accelerators. The phase resolution of such monitors depends crucially on accuracy of fabrication and tuning of RF-deflector, thus preliminary simulations of its electrodynamic characteristics are of importance for subsequent commissioning of the monitor. Simulations of some basic operational electrodynamic parameters and results of experimental measurements are presented.
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Paper

Title

Page

Development of the INR Linear Accelerator DTL RF System

191

A.I. Kvasha, V.L. Serov
RAS/INR, Moscow, Russia
A. Feschenko
MIPT, Dolgoprudniy, Moscow Region, Russia

The regular INR DTL RF system operation began in 1992. By this point three new type of vacuum tube, designed purposely for INR linear accelerator, were manufactured at OKB "Swetlana" in the amount sufficient for RF system operation during 20 years. Among them were two vacuum tubes for final RF power amplifier - GI-54A and RF driver - GI-51A and also vacuum tube for powerful anode modulator - GMI-44A. In the late 80s manufacture of these vacuum tubes was stopped and since 1990 designing of new vacuum tube for RF output power amplifier instead of GI-54A was started. The new vacuum tube GI-71A with output RF power up to 3 MW in pulse, plate power dissipation up to 120 kW and power gain about 10 was simpler and less expensive in comparison with GI-54A. The transition to new vacuum tube began in 1999 and finished in 2014. Successful testing of GI-57A as RF driver, fulfilled in 2008, opened the possibility of replacement GI-51A. As for GMI-44A replacement there are no analogues, produced in Russian federation, and, as it turned out, the only option was GI-71A again. Below some problems, connected with the vacuum tubes replacement, as well as main results of twenty years DTL RF system operation are considered.

Slides THXSH01 [4.748 MB]

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TUZMH02

INR High Intensity Proton Linac. Status and Prospects.

48

A. Feschenko, L.V. Kravchuk, V.L. Serov
RAS/INR, Moscow, Russia

The status and the prospects of High Intensity INR Linac are presented. The routine beam intensity is equal to 130 mkA. The annual accelerator run duration is about 1600 hours. The main beam user facilities are multipurpose complex for neutron science, isotope production facility and proton therapy facility. The primary activities are accelerator maintenance, modernization of accelerator systems and beam transportation channels, increasing of accelerator reliability, improvement of beam parameters.

Slides TUZMH02 [7.267 MB]

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reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)

THCBSH01

INR RAS Instrumentation for Bunch Shape and Beam Cross-Section Monitoring

204

S.A. Gavrilov, A. Feschenko, P.I. Reinhardt-Nickoulin
RAS/INR, Moscow, Russia

Instruments for bunch shape and beam cross-section diagnostics at ion linacs are as important as complicated devices. Widespread Bunch Shape Monitors developed in INR RAS are used during a linac commissioning and optimization of beam dynamics. Beam Cross-Section Monitors implemented at INR RAS linac provide efficient non-destructive beam tuning and control. Features of both monitors investigated in simulations and beam tests are described. A variety of experimental results are presented.

Slides THCBSH01 [12.054 MB]

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reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)

TUPSA004

Proposal of the Accelerating Structure for the First Cavity of the Main Part of INR Linac

216

I.V. Rybakov, A. Feschenko, Y.Z. Kalinin, L.V. Kravchuk, V.N. Leontiev, A.N. Naboka, V.V. Paramonov, V.L. Serov
RAS/INR, Moscow, Russia

For the beam intensity and overall stability improvement of INR linac replacement of the first four section cavity of the main part is required. The present cavity is realized as the Disks and Washers (DAW) structure. The new cavity should not lose to the present one in electro dynamical parameters with minimal modifications in the rest linac systems. As the possible structures for the first cavity replacement both proven in exploitation structures and promising developments were considered. The analysis of electro dynamical parameters, coupled RF heating, mechanical processes and manufacturing analysis were performed for the considered structures. For further development the Cut Disk Structure (CDS) option is proposed as the structure with satisfying RF parameters and having the smallest transverse dimensions in comparison with analogues. For the production simplification with minimal losses in electro dynamical parameters an unification of the main geometrical parameters for the four sections cells was performed. The possibility of multipaction in the cavity is considered and an option for its damping is proposed. The manufacturing tolerances for the structure are estimated.

Export •

reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)

THPSC055

Electrodynamic Characteristics of RF-Deflector for Bunch Shape Monitor

659

D.A. Chermoshentsev, A. Feschenko, S.A. Gavrilov
RAS/INR, Moscow, Russia
D.A. Chermoshentsev
MIPT, Dolgoprudniy, Moscow Region, Russia
D.A. Chermoshentsev
Skoltech, Moscow, Russia

Bunch shape monitors, based on a transverse RF-scanning of secondary electrons, are used for measurements of particles longitudinal distribution in bunches at different linear ion accelerators. The phase resolution of such monitors depends crucially on accuracy of fabrication and tuning of RF-deflector, thus preliminary simulations of its electrodynamic characteristics are of importance for subsequent commissioning of the monitor. Simulations of some basic operational electrodynamic parameters and results of experimental measurements are presented.

Export •

reference for this paper using ※ BibTeX, ※ LaTeX, ※ Text/Word, ※ RIS, ※ EndNote (xml)