Linear Accelerator Conference LINAC2010 - List of Authors (Benwell, A.L.)

A B C D E F G H I J K L M N O P Q R S T U V W X Y Z

Benwell, A.L.

Paper	Title	Page
THP064	Design of the Second-Generation ILC Marx Modulator	899
	M.A. Kemp, A.L. Benwell, C. Burkhart, R.S. Larsen, D.J. MacNair, M.N. Nguyen, J.J. Olsen SLAC, Menlo Park, California
	The SLAC National Accelerator Laboratory is leading an effort to design a prototype Marx modulator to meet the ILC klystron modulator specifications; a 120 kV (± 0.5%), 140A, 1.6 ms pulse at a 5 Hz prf. A first generation prototype, the P1 Marx, has been developed and is undergoing life testing. The design of a second-generation Marx, P2, has been completed and most sub-systems have been tested. The P2 advances the Marx topology demonstrated by the P1; eliminating single-point failures, incorporating advanced diagnostics/prognostics, and optimizing engineering margins to improve system availability. The P2 consists of 32 cells, which are individually regulated at an output of up to 4kV. This is in contrast to the P1 Marx which is collectively regulated by a series "Vernier" Marx. The 30 of 32 cell redundancy allows for up to two cell failures without degrading the modulator output. Failed cells can be quickly replaced and remotely-serviced. This paper presents the design of the P2 Marx. Specific topics discussed include the control architecture, mechanical layout, and power electronics design. Experimental results of both a single and array of cells are presented. C. Burkhart, et al., "ILC Marx modulator development status," LINAC, 2008. ** K. Macken, et al., "Towards a PEBB-Based Design Approach for a Marx-Topology ILC Klystron Modulator," PAC, 2009.

Paper

Title

Page

THP064

Design of the Second-Generation ILC Marx Modulator

899

M.A. Kemp, A.L. Benwell, C. Burkhart, R.S. Larsen, D.J. MacNair, M.N. Nguyen, J.J. Olsen
SLAC, Menlo Park, California

The SLAC National Accelerator Laboratory is leading an effort to design a prototype Marx modulator to meet the ILC klystron modulator specifications; a 120 kV (± 0.5%), 140A, 1.6 ms pulse at a 5 Hz prf. A first generation prototype, the P1 Marx, has been developed and is undergoing life testing*. The design of a second-generation Marx, P2, has been completed and most sub-systems have been tested**. The P2 advances the Marx topology demonstrated by the P1; eliminating single-point failures, incorporating advanced diagnostics/prognostics, and optimizing engineering margins to improve system availability. The P2 consists of 32 cells, which are individually regulated at an output of up to 4kV. This is in contrast to the P1 Marx which is collectively regulated by a series "Vernier" Marx. The 30 of 32 cell redundancy allows for up to two cell failures without degrading the modulator output. Failed cells can be quickly replaced and remotely-serviced. This paper presents the design of the P2 Marx. Specific topics discussed include the control architecture, mechanical layout, and power electronics design. Experimental results of both a single and array of cells are presented.

* C. Burkhart, et al., "ILC Marx modulator development status," LINAC, 2008.
** K. Macken, et al., "Towards a PEBB-Based Design Approach for a Marx-Topology ILC Klystron Modulator," PAC, 2009.