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HCRPAEM,N / Macao |
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CERN
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SY
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SY-EPC
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Under Development. Prototype expected mid 2016
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| MACAO | Medium size Acdc COnverter |
| Power In | 3 x 400V with Neutral / 1A |
| Power Out | 500 W max in the range of |
| +/- 12.5A, +/-150V | |
| Converter Type | 4 Quadrant |
| Control type | FGC3 / Ethernet+ |
| Current Accuracy | 2 mA @ week |
| 5 mA @ year | |
| (1 ppm=xxuA=0.0xxmA) | |
| Voltage Ripple | 10 mVrms@ f=20Hz-1kHz |
| 60 mVrms@ f=1kHz-130kHz | |
| 7 mVrms@ f=130kHz-5MHz |
Design & Operation Responsibles
| Responsibles: |
Serge PITTET
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Ludovic CHARNAY
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CERN SY-EPC-LPC
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Power Converter Architecture
This Power Converter is used in Injector Machines to power warm magnets, for DC or pulse applications.
Different parts were designed and produced separately, Power Converter being finally integrated in a housing rack, with 3 main parts:
- High Precision Current sensors (DCCTs), able to measure DC or pulse current at the required precision.
- Power Part: Power Rack and its removable Power Module
- A Digital Controller (FGC) using Ethernet bus in charge of:
- The high level control from and to the Cern Control Room
- The high precision digital current loop
- Collecting and reporting all status, faults, and measurements from all the different parts to the remote services, for diagnostic and operation purposes.
Power Converter simplified Architecture .ppt or .vsdx
Power Part
Voltage Source is based on a full bridge phase shifted topology followed by a 4 quadrant switching stage to allow the 4 quadrant operation.
One DCCT is used for the high precision current loop (FGC), and is located directly in the voltage source, even if not used by it to operate as a pure voltage source.
Converter is compatible with 19'' standard dimensions.
| Power In | 3 x 400V with Neutral / 1A |
| Power Out | 500W max |
| Cooling type | Fans |
| Converter Weight | Power Module ............ 23? kg (FGC Included) |
Power Part simplified Architecture / Topology .vsd
Typical Curves
| Output Voltage Ripple | TBD |
Control Part
Control & regulation principles are summarized in a detailled schematics representating only the part involved in the output current regulation scheme. FGC3 control can adapt quite easily with different possible scenarios.
I.Loop, I.sensor = power
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I.Loop=fgc, I.sensor=power
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I.Loop=fgc, I.sensor=external
Regulation Control simplified schematic .vsd
High precision current control loop is managed by the digital controller called FGC (Function Generator Controller). This unit includes a high precision Sigma Delta Analog to Digital Converter which digitalize the analog current measurement coming from 1 or 2 Current sensors (DCCTs: DC current Transducer). Precision is then directly relying on sensor precision: current sensors, the ADCs, and the algorithm being used for the regulation loop. Voltage source is then used as a power amplifier, powering the load through a high bandwidth voltage loop.
Magnet Protection
Power Converter is part of magnet protection scheme, even if not directly fully responsible of the monitoring and diagnostic of the magnet status. WIC (Warm Interlock Controller) can interlock Power Converter if magnet safety requires it.
Power Converter is then expected to:
- Always ensure that external protection system can stop the Power Converter through a safe signal called Fast Abort.
- Stop powering the load in safe way (handling the magnet energy even when stopping, through dedicated system called crowbar). This active system provides a safe resistive discharge path for magnet current (energy).
- Monitor Earth current of the total circuit: converter + load (magnet and its DC cables), and take the right action if threshold reached.
- Crowbar
The system is based on a 200 mOhms power resistance connected to two mosfet which are closed when the converter is off or standby.
Crowbar System simplified schematic .vsd
- Earth System
Detection system is an active / passive system, since relying on a converter state-controlled 100mA current source powering a 100Ohms resistor connected between earth and negative polarity of the Power Converter. A common mode voltage is then created, (100mA x 100Ohms = 10V) making possible to detect an earth fault even with converter being OFF (not condamned). A 10 Ohms resistance series a fuse only being connected between negative polarity and earth. Active system can be disabled through an internal jumper.
Earthing System simplified schematic .vsd
Power Converter Components
A power converter is actually a sum of different equipments under several different sections in the SY-EPC group. The modularity is a key factor for easier maintenance with regards to MTTR reduction.
- Power Module
- 2x Current sensor: 12A DCCT
- Digital Controller: FGC3 + FGC3-dongle
- FGC3 Fan unit
Magnet Types
| corrector | TBD |
Machine Installation
| Air losses | Module @ P.nom (incl. FGCs) | 100 Watts |
| Water losses | Module @ P.nom (incl. FGCs) | none |
| SPS Use | 333+27 MACAO_05 Power Converters |
Production Contract & Contact History
| Developped |
CERN SY-EPC-LPC
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| 2015-2016 | ||
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Serge PITTET
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Vincent BARBET
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| Production | xxx MACAO_05 Power Converters |
333+27 for SPS (2018) |
Converter Circuit Names
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