Team Infrastructure Detector Support System Low Voltage (Preamp, Digitiser ) High Voltage System Cryogenic Autofill Process Control Graphical User Interface Host Laboratories Grounding Meetings 2007: 11/1 AW Orsay 9/2 18/4 3/5 21/5 8/6 26/6 24/7 4/9 20-21/9 Konnevesi 11/10 23/10 AW Legnaro
AGATA Infrastructure Team Meeting Konnevesi, Finland 20-21 September 2007
Design & Infrastructure II (Session 9 Summary) Host Lab Issues LNL (A. Gadea) GANIL (M. Tripon) Detector Support System (Ch. Veyssiere) High Voltage for AGATA (Ch. Veyssiere)
AGATA Demonstrator at LNL Infrastructures installation A.Gadea INFN-LNL
Support Structure Mechanics: -Design completed by STFC Daresbury early summer 2007 -Machining of the flanges done by INFN Padova, Milano and LNL -16 Flanges ready, excluding limited machining at LNL. -Mounting test (5 flanges) performed end of June. Required tooling for accurate mounting -Surface treatment expected ready by December 2007 -Mounting test 15 flanges Dec. 2007 Jan. 2008? TEST Flange AGATA -Purchased the pre-machined parts to build the under-lying (welded) structure -Design of the LN2 cryogenic line support by STFC ready. -Scheduled the construction of the structures from December LNL 06/07
DIGITIZERS LOCATION 8 DIGITIZERS 8 DIGITIZERS 2 x 47/55U racks 21 width
Conditioned room DAQ (and PSA) in Exp. Hall 3 AGATA Ge-detector Lab. Infrastructure Installation ongoing Water cooled racks for pre-processing 75m AGATA control-box ACQ-Run Control pre-processing. Infrastructure installation ongoing
Requested support of the collaboration at LNL: - Dec. 2007 Feb. 2008 (Mech.) test and check of the mechanics. 15 flanges mounting test as soon as tooling is available. - April 2008 June 2008 (Mech., Infr., Elec., DAQ) Mounting of the mechanics in the final location. Grounding tests. Installation and test of the DSS LN2 LVPS/HVPS. Test of the Digitizers in the final location. Test of the signal transmission trough optical link? Start installation of the PSA and DAQ farms. - July 2008 Nov. 2008 (Det., Mech., Infr., Elec., DAQ) Installation of the first detector modules. Test and check mounting and positioning the detectors Commissioning DSS with detector modules Installation and commissioning electronics and DAQ
Cabling and infrastructure for the electronics and DAQ Modification and Installation of racks for pre-processing Cable guide and modification of the cable tray for PRISMA N.2 Digitizer Racks (47U) TR2-Racks for the DAQ at LNL Ge Detector laboratory Cryogenic infrastructure Vacuum oven PLC control N.2 AXIS AGATA low voltage power supply modules Workstation for test bench DAQ Electronics for test bench DAQ Vacuum gauges Electronics Laboratory Basic instrumentation ATCA crate Switch for crate ATCA Total investment through INFN-AGATA project: 175k
AGATA Demonstrator@GANIL Introduction Experimental area and rooms Mechanics Cables Cost Planning GANIL manpower
AGATA Demonstrator@GANIL Mechanics AGATA in VAMOS experimental area radius from the target to the crystal 130mm with 8TC and 5 exogam clovers radius from the target to the crystal 234mm with 8TC and 8 exogam clovers Vamos platform can rotate from 0 to 45 GANIL/ Michel Ozille AGATA Detector mechanical meeting, Legnaro 18/09/07
G1 Low Voltage Power supplies LVs LV AGATA Demonstrator@GANIL Cables Profibus Sensors TCs, HV boxes Local PC Ethernet PLC crates Valves Valves Network Digitizers control (set-up, inspection lines, pulser): - IP numbers, VNC access, rate, OF or Cu? What are links between LLP and PSA? Cabling documents: - List of the whole main cables (type, length, label)? - AD cabling diagram (from TCs to PCs farm)? 019 Preamps Network Digitizers Ethernet Ethernet switches Network Digital Samples LLP ATCAs PSA PCs VME (AGAVA) Time Stamping
Mechanics AGATA Demonstrator@GANIL Cost Infrastructure AD platform Target support Digitizers cabinet Alignment tools Rooms renovation and utilities (electricity, LN2 line, water cooling, network, air conditioning,..) Cables Cables (Optical Fibers for AGAVA, coaxial, ) Cabling Equipment TOTAL AGAVA modules ATCA & PC farm cabinets EXOGAM autofill Batteries (*2), (1kW, 10h) Tank (stocking room) Autofill (stocking room) Power supplies (LV and HV) NIM crate (test room) TNT2 (*2), (test room)) Oscilloscope (test room) Pulse generator (test room) Annealing equipment (pump, valve, oven) 8 k 7 k 3 k 5 k 23 k 20 k 10 k 2 k 12 k 12 k 18 k 7 k 14 k 15 k 7 k 10 k 6 k 10 k 10 k 6 k 20 k 135 k 190 k
AGATA demonstrator DSS -Low voltage: -Control/command: P. GROS R. TOUZERY; S. BROUSSARD
AXIS technical proposal (studies) Test contact One connector for 3 digitizers 3 connectors for 3 digitizers On/off switch +/-6V & +/-12V +6.5V +48V & +5V +24V & Profibus
Connections on the detector ±6V; ±12V in 1 x sub-d25 LN2 1 x sub-d9 ±6V; ±12V out 3 x sub-d9 HV in 1 x sub-d15 Profibus in M12 or Fischer Profibus out M12 or Fischer Top view Bottom view
Data block exchange principle GUI 6 1 READ Bloc CPT_R Ethernet network WRITE Bloc CPT_W INSIDE PLC Write_flag 2 CMD_R CMD_W 3 Write_flag = 1 DATA_R 4 YES Periodic cycle GUI / PLC communication sequence : 1 GUI increase CPT and Process Bloc 5 Process Bloc CPT_P send WRITE Bloc to PLC 2 copy CPT_W in CPT_P 3 if Write_flag= 1 DATA_P CMD_P then copy CMD_W in CMD_P 4 copy CPT_P in CPT_R copy CMD_P in CMD_R 5 copy DATA_P in DATA_R PLC Program 6 PLC send READ Bloc to GUI OUTPUT Profibus DP network INPUT
Automatic Mode (PLC Process and GUI Automatic mode Control) Time > 12H NO YES FILL NOW Command NO YES Temperature Alarm NO YES x8 detectors Pressure and level of tank OK Detector X selected All Detectors Closed Open tank and purge valves Open detector X Valve Waiting for return LN2 in Tank Pipeline Full Detector X Full or stop fill Time >? min Close tank valve Close Detector X Valve Close Tank Valve
Work being done List of the parameters corresponding to the process and the GUI commands Communication means between PC and PLC (by data block exchange) Collaboration with Tobias Habermann from GSI: Visit in Saclay last week to understand the difficulties of each others Wish to make a specification document for GUI and process (description of displays, running modes ) Finalize a first version of data blocks and realize a GUI prototype within 2 weeks
AGATA Demonstrator High voltage A. BOUTY; Y. MARIETTE; T. BOUSSUGE
As defined in «DSS performance specifications» V.E at: https://project-agata.cea.fr/groups/infrastructure/ Summary of the main functionalities (1/2) Mounted on the cryostat Connected to the slow control via Profibus-DP Connection to the ISEG HV module are: Vset (0 2.5V corresp. 0 5kV) Imon (current monitoring) (0 2.5V corresp. 0 10µA) Vmon (output voltage monitoring) (0 2.5V corresp. 0 5kV) The HV module has embedded HVmax, Imax, Tmax, RampUpmax, RampDownmax, ID number.
Hardware: : prototype boards n 2n 4 Profibus DP OUT CABSD100 BOARD 5 BSD OUT Profibus DP IN 1 AGILIPLUG (Profibus DP interface) Power supply 6.5V BSD IN or PT100 2 CMHV200 BOARD 3 ISEG
Difficulties to reach the specs due to ISEG module Difficulties to obtain technical informations from ISEG But we think the MHp 50 103 5 2.5 has the following problems: Accuracy on current measurement not at the level of few na HV output not inhibited at start and stop Noise at 56.34kHz (chopping frequency) Short circuit protection not present
Current measurement: formula We tried to understand what it could correspond to: V Imon ISEG module 125kΩ Rimon Rmess IOUT DC/DC 500MΩ VOUT Rload V Vmon
Current measurement: formula If this is true, we should have: V V out out = = R R load mes I I out mes V Imon ISEG module Imon 125kΩ Rimon Imes Iout DC/DC 500MΩ Rmess Vout Rload I = I + mon out I mes V Vmon I out = V R I mon I mon V R out mes Very similar to: I µa V V = V OUT I MON Rmess out 8 If we plot this for various I out at different voltages : V I mon R = I mon I out + V R out mes
Current measurement: bench Power Supply 230V HV BOX Hardware: CMHV100/HV100 cards Software embedded : AGATA_DEV_2_0_ 6.5 V 300mA Serial cable Laptop with Acquisition Software Bench v 1.0.0. Coaxial High voltage Cable (Draka htc-50-1-1) PT100 cable Resistors Block Gauge High voltage resistor I load Multimeter 2001 KEITHLEY HV Module R load KEITHLEY 2001 Accuracy ±0.4nA R load 230V Grounding Grounding
Current readout vs. output high voltage Current Readout (ADC code decimal) 65536 49152 32768 13107 19660 26214 32767 39321 45875 52428 58981 65535 16384 Vimon = F(Iout) with Vout = Cst 13107 => 1kV 65535 => 5 kv step = 500 Volts 0 0,000 2,000 4,000 6,000 8,000 10,000 12,000 Current (µa) This shows the difficulties to calibrate one HV module
HV not inhibited at start and stop: measurements measurements State upon Power Up Power supply No more Vout~200V but dangerous for ADC (latch-up) 2 switches to be set to protect the ADCs VImon Current Readout is about 1V Vout State upon Power Down Power supply Current Readout is about 1,23 V VImon Vout Output CPLD
Measurement on voltage noise density: HV is set to 1kV Test bench layout: Oscilloscope Grounding 230V Serial cable HV module 6.5 V 300mA Power Supply 230V 230V Grounding Grounding Ouptut HV = 1000V Spectrum analyser 230V Vset at 0 V from 0Hz to 150kHz Grounding F chopping (ISEG)= 56,34kHz
What s next? Performances to be checked by GSI Different options: Everybody agrees with the ISEG module as it is The HV module should be defined again: Temporary solution for the first months of the demonstrator (with a CAEN crate for instance) The temporary solution becomes the final one. Difficulties to estimate schedule and costs
Team Infrastructure : Summary Detector Support System LV Ordered HV Ongoing Detector tests end Nov, Prototyping & production when and in line with cryostats Core systems ready for installation AG : April 2008 June 2008 onwards GUI ongoing, close links with Host Labs Cabling, Numbering for AD