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Introduction Slow Controls Power Supply Special Magnets Controls Status and Plans Tobias Stadlbauer Special Magnets MedAustron 7-8 October 2010 AOB Introduction Slow Controls Power Supply Content Devices covered by Special Magnets Controls Cooling Controls Position Controls Power Supply Controls Tobias Stadlbauer PP-101007-a-TST 2 AOB Introduction Slow Controls Power Supply AOB Devices covered by Special Magnets Controls Magnetic Septa (cooling controls) (2 systems) Fast Pulsed Magnets (cooling controls) (for MKC in-house, rest part of tender) Electrostatic Septa (remote position controls) Power Supplies (2 high voltage DC, 6 fast pulsed) Tobias Stadlbauer PP-101007-a-TST 3 Introduction Slow Controls Power Supply AOB Control architecture for Special Magnet Systems Tier 3 Technical Network Slow Control Tier 4 FEC FED Industrial fieldbus R Main Timing System Optional Optical trigger (optional) Supervisory Control System PCC PCO FED Regulation Board Slow control & digital set-point/ measurement Analog O(250) Power Converter Magnet Tobias Stadlbauer PP-101007-a-TST 4 Device Analogue and Digital IO Technical Network Fast Control Example: PCO interface R FECOS Tier 2 Generic layout Special Magnets Controls sees responsibility for the green blocks Introduction Slow Controls Power Supply AOB Slow control for Special Magnet overview Element Name FEC Power supply FED Position control FED Cooling Alarms FED Timing LEBT fast deflector EFE PCC “PCO FED”* Electrostatic septa ESI, ESE PVSS? PLC Injection Bumpers MKI PCC “PCO FED”* Magnetic septa MSI, MSEa, MSEb PCC PVSS? PCO(1) Dump bumpers MKS PCC “PCO FED”* MTS EXT. Tune kickers MTV, MTH PCC PCO* MTS (RF?) EXT. Chopper dipoles MKC PCC (BDCS) “PCO FED”* (BDCS) MTS (BDCS) EXT. (Medical Device) PLC PP-101007-a-TST 5 CERN TE-ABT CERN TE-ABT MTS PLC(2) * No optional regulation board Tobias Stadlbauer MTS Local control System (LCS) EXT. (1) EXT. (CERN TEEPC) (2) CERN TE-ABT Introduction Slow Controls Power Supply AOB Cooling Controls – example: Thin Magnetic Septa PLC [7,8] Tobias Stadlbauer PP-101007-a-TST 6 Introduction Slow Controls Power Supply AOB Position Controls: Electrostatic Septum PLC Tobias Stadlbauer PP-101007-a-TST PP-101007-a-TST 7 BIS (Beam Interlock System) [7,8] Introduction Slow Controls Power Supply AOB Architecture for power supply controls R R Main Timing System Optional Optical trigger (optional) Supervisory Control System PCO FED PCC Regulation Board Slow control & digital set-point/ measurement Analog O(250) Power Converter Magnet [8] Tobias Stadlbauer PP-101007-a-TST 8 Introduction Slow Controls Power Supply AOB State Diagram for Special Magnet power supplies ON States OFF STANDBY ON OFF & FAULT ON ON OFF STANDBY PP-101007-a-TST OFF & FAULT STANDBY DEFECT OFF OFF RESET & NOMINAL Conditions A DEFECT is a condition which will cause an interlock. A NOMINAL condition is one in which there are no interlocks and hence no DEFECTs. Tobias Stadlbauer RESET & DEFECT STANDBY Commands OFF STANDBY ON RESET DEFECT GLOBAL OFF which is a state of the power supply in which the entire system (including CONTROL/ELECTRONICS and any AUXILIARY services) is switched off through a main circuit breaker. Manual action is required to transition the power supply from the GLOBAL OFF condition into the OFF state: a transition from the GLOBAL OFF condition into any other state is not permitted. 9 Introduction Slow Controls Power Supply AOB Commands A Command is defined as something that is recognized by the Power Supply and drives the Power Supply between two states. The Commands for the Power Supply are: OFF: If no DEFECT is present, the power supply is transitioned to the OFF state. In this state the outputs of the AC power sections of the system are switched off through a magnetically actuated circuit breaker. CONTROL/ELECTRONICS and any AUXILIARY services are powered on. STANDBY: If no DEFECT is present, the power supply is transitioned to the STANDBY state. In this state the outputs of the AC power sections of the system are energized, and ALL power semiconductors are in the off-state (i.e. zero current in the load). Only the triggers for the switched elements of the power supply are inhibited. ON: If no DEFECT is present, the power supply is transitioned to the ON state. In this state all circuits are energized and the trigger gates are enabled. The power supply will pulse upon the receipt of appropriate timing signals. RESET: After all DEFECTs are cleared, and a RESET command is issued, the power supply will transition to the OFF state. Accidental depression of the RESET button must not result in any hazardous operation. Tobias Stadlbauer PP-101007-a-TST 10 Introduction Slow Controls Power Supply AOB Timing and Control for Special Magnet power supplies (1) Electrode Voltage (kV) LEBT fast deflector (EFE) The MedAustron Control System will provide: 3 2.5 2 1.5 1 0.5 0 -40 -20 0 20 40 60 80 Time (µs) 100 120 140 160 •The necessary timing pulses (START and STOP) to drive the power supply; •The state commands and the value of the voltage reference for the present cycle (fixed?) Magnetic Induction (mT) Injection Bumpers (MKI) The MedAustron Control System will provide: 28 24 •The necessary timing pulse (START), synchronised with the LEBT Deflector to drive the power supply; •The state commands and the value of the voltage reference for the present cycle •The value of the slope length 20 16 12 8 4 0 -40 -20 0 20 40 60 80 100 120 140 160 Time (µs) Tobias Stadlbauer PP-101007-a-TST 11 Introduction Slow Controls Power Supply AOB Control and Timing for Special Magnet power supplies (2) Dump bumpers (MKS) Magnet Current (A) 1,400 The MedAustron Control System will provide: •The necessary timing pulse (START) •The state commands •The value of the magnet current reference for the present cycle (need Btrain to track beam energy) 1,200 1,000 800 600 400 200 0 500 450 400 350 300 250 200 150 100 50 0 Time (µs) Tune Kicker (MTV, MTH) 1.2A The MedAustron Control System will provide: •The necessary timing pulse (START and STOP), synchronised with the RF train (ns precision) to drive the power supply; •The state commands and the value of the current reference for the present cycle 0.8A 0.4A 0A -0.4A 0s 0.5us I(LMAGNET)/1190 1.0us Tobias Stadlbauer PP-101007-a-TST 1.5us 2.0us 2.5us 3.0us 3.5us 4.0us 4.5us 5.0us Time 12 Introduction Slow Controls Power Supply AOB Timing and Control for Beam Chopper Power Supply (PKC) Magnet Current Imag tr ton tf toff Time The MedAustron Beam Delivery control system will provide: •The state commands and the value of the magnet current reference for the present cycle; •The necessary timing pulses (START and STOP) to drive the power supply; To reduce the probability that the PKC will receive an incorrect command to remain in the on-state (e.g. due to a faulty trigger card), a timing protocol using two independent timing inputs is envisaged. These two inputs would be “ANDed” in the LCS of the PKC to derive the required trigger state: a HIGH level on BOTH input lines represents a START signal, whereas a LOW level on either or both lines, represents a STOP signal. The “AND” unit must be failsafe, i.e. if it or its power supply fails it must give a low level output. Tobias Stadlbauer PP-101007-a-TST 13 Introduction Slow Controls Power Supply AOB Status Magnet Slow Control Requirements almost finished. Engineering Specification Documents for: MKC, MKI, MTH, MTV including control interfaces, published Supply of Special Magnets and Their Power Supplies, TECHNICAL DESCRIPTION (now in 1st stage of 2 stage tender process) Tobias Stadlbauer PP-101007-a-TST 14 Introduction Slow Controls Power Supply AOB Planning Study, design and specify LEBT Deflector system: Electrostatic deflector (CNAO design), generator and control. End week 43, 2010 Study and specify fast pulsed magnets control End week 51, 2010 Study, specify and produce control for electromagnetic septa End Week 9, 2011 + ongoing activity for production Study, specify and produce control for electrostatic septa with focus on motorization prototyping and high voltage power supply specification End week 31, 2011 Tobias Stadlbauer PP-101007-a-TST 15 Introduction Slow Controls Power Supply AOB References [1] J. Borburgh, M. Barnes, T. Fowler, M. Hourican, T. Kramer. T. Stadlbauer, Special Magnets - Final Design Report, CERN, 2010 (unpublished). [2] J. Gutleber, R. Moser, MedAustron Control System Architecture and Design Document, MedAustron, ES-1000406-a-JGU. [4] T. Fowler, T. Kramer, T. Stadlbauer, Special Magnets Control System Requirements Specification Document, CERN, unpublished. [5] J. Gutleber, R. Moser, Main Timing System and Signal Distribution Services, MedAustron, unpublished. [6] J. Borburgh, et al., “MedAustron Special Magnets - WP description”, CERN, Geneva, 2009 [7] M. Marchhart, T.Glatzl “Magnet Slow Control - Requirements”, MedAustron [8] T. Glatzl “Overview Magnet Slow Control”, MedAustron, 2010 Tobias Stadlbauer PP-101007-a-TST 16