1. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
High Voltage and Low Voltage
System Review
I.N.F.N. Naples
Introduction
Detector description
Requirements
SASY and EASY prototypes tests
Systems description
Cables and connectors
Solutions and costs
Board production and test
Conclusions
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

2. Introduction I
I.N.F.N. Naples
The CMS sub-detectors will be equipped with a large part of the HV and LV systems placed around the detector; in a not “easily accessible” area.
The CMS and ATLAS RPC groups are investigating the possibility to have both the systems around the detector, working in a very hard conditions for the high magnetic field and high radiation environment.
The LHC RPC groups, in collaboration with the CAEN, have designed and tested an HV-LV prototype (SASY 2000) able to work in an hostile area. The system is based on the idea to split in two the HV and LV systems:
LOCAL: Central system (mainframes) placed in control room;
REMOTE: distribution system placed around/on the detector, consisting of a crate housing the HV and LV boards.
A natural evolution of the SASY2000 has been presented to CMS (May 03) by the CAEN company: EASY system.
Different solutions have been analyzed by the CMS RPC group
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

3. Detector description I
I.N.F.N. Naples
There are 3 different kind of chambers with 2 or 3 bigaps and equipped with
6 or 12 or 18 Front-End Boards
RB2/3
Bigap
ALV1
DLV1
ALV2
DLV2
HV1
HV2
RB3 and RB4
ALV1
DLV1
ALV2
DLV2
HV1
HV2
Bigap
RB1 and RB2/2
Bigap
ALV1
DLV1
ALV2
DLV2
HV1
HV2
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

4. Detector description II
I.N.F.N. Naples
RB1/RB2in
RPC chamber
Front-End
Bigap
Distrib. board
Bigap
ALV1
DLV1
ALV2
DLV2
ALV Analog Voltage = 7V Absorb. (6FEBs) = 0.42 A
DLV Digital Voltage = 7V Absorb. (6FEBs) = 0.9 A
I2C input
LV+I2C FEB out
LV in
Distributes analog and digital LV
It supplies LV power to 3 FEB chains
It supplies the I2C main line from LB
and one backup line from DT.
Total power/(ALV+DLV) ch.: 1.32 A * 7 V = 9.24 W
Expected Power  120 W/sector  7.2 kW/Barrel
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

5. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
Barrel wheel overview
I.N.F.N. Naples 1 2 3 4 5 6 7 8
Muon racks 12 11 10 9
5 CMS wheels
12 sectors
balcony
12 sectors * 5 wheels = 60 sectors
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

6. HV-LV schema for a Barrel sector
I.N.F.N. Naples
78 FEBs = 13 ALV+13 DLV ch bi-gaps = 34 HV ch.
DT chamber
RB4
2+2 LV
6 FEBs / 2 bi-gaps
6 FEBs / 2 bi-gaps
4+4 HV
DT chamber
RB3
2+2 LV
6 FEBs / 2 bi-gaps
6 FEBs / 2 bi-gaps
4+4 HV
6+6+6 FEBs / 3 bi-gaps
6 LV
6 HV
RB2
DT chamber
4 LV
6+6 FEBs / 2 bi-gaps
4 HV
4 LV
6+6 FEBs / 2 bi-gaps
4 HV
RB1
DT chamber
4 LV
6+6 FEBs / 2 bi-gaps
4 HV
2 bi-gaps = 96 strips = 6 FEBs
LVD channel
HV channel
LVA channel
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

7. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
System requirements I
I.N.F.N. Naples
General requirements:
working in high magnetic field (up to 2 Tesla);
working in an high radiation environment (5*1010 p/cm2 & 5*1011 n/cm2 & kRad);
local system in control room + distributed remote systems on the detector (at least for the LV);
redundancy of the control electronic devices (mP per board)
input voltage from the CMS AC/DC 48V power supply;
looking forward common CMS solutions in order to simplify the hardware and software development/maintenance of the systems
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

8. System requirements II
I.N.F.N. Naples
HV requirements:
12KV/1mA
Ripple < 100 mV pp at load per f < 20 MHz
Programmable voltage 0-12KV
Voltage step 10V
Voltage precision < 10V
V/I/Trip/Status control and monitoring
Error/Power leds
LV requirements:
7V/3A
Ripple < 10 mV pp at load per f < 20 MHz
Programmable voltage 0-8V
Voltage step 100 mV
Voltage precision 100 mV
V/I/Trip/Status control and monitoring
Individual ON/OFF
Error/Power leds
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

9. System requirements III
I.N.F.N. Naples
Control and monitoring system requirements:
Common hardware and software (PVSS II) solution;
Detailed control/monitoring of the remote channels:
voltage/current and temperature
protections, errors and hard-reset for communication lost.
A second independent way to control them (telnet/ssh......)
Design requirements:
Possibility to easily increase the HV granularity;
Possibility to easily fix RPC problems:
disconnect high-current/sparking gap/bi-gaps;
modify the HV map in order to group bi-gaps with same working point;
Possibility to measure the RPC working-point in standalone.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

10. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
HV-LV system design
I.N.F.N. Naples
Different HV and LV designs have been analyzed in order to reduce the total cost preserving the system requirements and the trigger functionality:
1 HV/bigap 2 LV/6FEBs; FULL OPTION
1 HV/chamber 2 LV/chamber; CHAMBER OPTION
1 HV/station 2 LV/station; STATION OPTION
Then we have analized two different solutions for both the HV and LV system based on the idea to have them on the detector or in control room.
HV in control room or HV on the detector
LV in control room or LV on the detector
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

11. HV-LV schema for FULL option
I.N.F.N. Naples
26 LV channels HV channels
Chambers have been designed with 2 gaps, of adjacent bi-gaps, connected to the same HV channel, in order to reduce the number of HV channels preserving the number of station available for the muon trigger
2+2 LV
6 FEBs / 2 bi-gaps
6 FEBs / 2 bi-gaps
2+2 HV
2+2 LV
6 FEBs / 2 bi-gaps
6 FEBs / 2 bi-gaps
2+2 HV
6 LV
6+6+6 FEBs / 3 bi-gaps
3 HV
4 LV
6+6 FEBs / 2 bi-gaps
2 HV
4 LV
6+6 FEBs / 2 bi-gaps
2 HV
4 LV
6+6 FEBs / 2 bi-gaps
2 HV
wheel 1 2 3 4 5
TOT
gaps
408
2040 HV
204
1020
FEBs
936
4680 LV
312
1560
FULL option
1 HV channel per 2-gaps
2 LV channels per 6-FEBs
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

12. HV-LV schema for CHAMBER option
I.N.F.N. Naples
16 LV channels HV channels
2+2 LV
6 FEBs / 2 bi-gaps
6 FEBs / 2 bi-gaps
1+1 HV
2+2 LV
6 FEBs / 2 bi-gaps
6 FEBs / 2 bi-gaps
1+1 HV
2 LV
6+6+6 FEBs / 3 bi-gaps
1 HV
Reduction of
2 LV
6+6 FEBs / 2 bi-gaps
1 HV
HV 1020  480 ch
LV 1560  960 ch
2 LV
6+6 FEBs / 2 bi-gaps
1 HV
2 LV
6+6 FEBs / 2 bi-gaps
1 HV
wheel 1 2 3 4 5
TOT
gaps
408
2040 HV 96
480
FEBs
936
4680 LV
192
960
CHAMBER option
1 HV channel per chamber
2 LV channels per chamber
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

13. HV-LV schema for STATION option
I.N.F.N. Naples
12 LV channels HV channels
2 LV
6 FEBs / 2 bi-gaps
6 FEBs / 2 bi-gaps
1 HV
2 LV
6 FEBs / 2 bi-gaps
6 FEBs / 2 bi-gaps
1 HV
2 LV
6+6+6 FEBs / 3 bi-gaps
1 HV
reduction
2 LV
6+6 FEBs / 2 bi-gaps
1 HV
HV 1020  360 ch
LV 1560  720 ch
2 LV
6+6 FEBs / 2 bi-gaps
1 HV
2 LV
6+6 FEBs / 2 bi-gaps
1 HV
wheel 1 2 3 4 5
TOT
gaps
408
2040 HV 72
360
FEBs
936
4680 LV
144
720
STATION option
1 HV channel per station
2 LV channels per station
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

14. Endcap Endcap layout (descoping) R2/1 R2/2 R2/3
RPC group
LHCC session
CERN
Endcap layout (descoping)
I.N.F.N. Naples
Endcap
Station 1
Station 2
Station 3
Total number of chambers: 432
10 degree sector
R2/1
R2/2
R2/3
High eta
Low eta
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

15. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
HV-LV Endcap numbers
I.N.F.N. Naples
Endcap
Layer RE1 RE2 RE3
# chambers 72*2 72*2 72*2
Assuming 1 HV channel/chamber & 6 HV ch x board
Layer RE1 RE2 RE3 TOT Boards Crate
# HV ch. 72*2 72*2 72* *2 6*2
Assuming 2 LV channel/chamber & 12 LV ch x board
Layer RE1 RE2 RE3 TOT Boards Crate
# LV ch. 144*2 144*2 144* * *2 ?
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

16. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
SASY 2000 prototype
I.N.F.N. Naples
SASY 2000 prototype
The HV-LV prototype 0 consists of: HV board (SA2001), 3 LV boards (SA2002) and 1 controller.
It has been split in three pieces, following a “logical separation” of the system, in order to study the functionality of every single piece and component.
The following tests has been performed on both the prototypes and will be repeated for the final boards:
Magnetic field test up to 7 KGauss (at CERN) (results shown by CAEN at CERN in May 2002)
Radiation test up to 10 LHC eq-years (at Louvain La Neuve) (results shown)
Test on the RPC to study the noise condition (to be performed at the test station in Bari);
High Stress Test to study the system under very hard conditions (under test in Napoli).
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

17. Neutron radiation test
I.N.F.N. Naples
The SASY2000 HV-LV prototype has been tested twice (May-Aug 2002) at the Louvain La Neuve radiation facility.
The total neutron fluence requests
for 10 LHC years is about 1x1012 n/cm2 (note: in RE1/1 region) corresponding to 2 hours and 40 min with a beam at 1 mA at 70 cm
SASY2000
In first session the system worked well for 30 min. corresponding to 1.8 • 1011 n/cm2 (a factor 6 higher than that expected on RB4!) We lost the communication with the prototype. CAEN reported a known loss of current gain due to irradiation on CNY17 opto-insulator used to enable the HV/LV channels. The prototype was irradiated for 80 min corresponding to 4.8*1011 n/cm2.
On the second prototype (ATLAS one) the gain current loss was cured using a lower value biasing resistor. Was registered a few SE on the controller with loss of communication but the normal condition was restored after 1 s on power OFF/ON condition (it will be implemented by firmware an HOT RESET to recover the communication without interruption of remote power supply).
After the irradiation the SASY2000 was tested outside, preserving its original functionality. (robustness of hardware)
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

18. Magnetic field test setup
I.N.F.N. Naples
Magnet: MNP24-1 at CERN Bldg. 168
B: up to 10 KGauss B around CMS: .44T
Test condition: 0-7 KGauss
Magnetic Field:
up to 5 KGauss
Test condition
SA2001: VOUT = 8kV, Rload=12 M
SA2002: VOUT0 = 4.7 V, VOUT1 = 5.0 V, IOUT0,1 = 1.9A
from 0 a 5 KGauss: loss of efficiency 2% (// B) 0% ( B)
(efficiency defined as =Pload/PDC-DC converter) (75%  73%)
Future improvements:
transformer oriented according  B  it will work reliably up to 8 KGauss
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

19. High Stress Test in Naples I
I.N.F.N. Naples
The High Stress Test system has been designed and developed by the group of Naples in order to make a complete test of any HV-LV power supply.
It consists of a test-box controlled by a PC running LabVIEW 6.1
At present the HST system is able to make:
Long term test: A cycle of measurements (voltage and current) made using different resistive charge (from 1M to 10 G) to explore the whole range of the PS.
Spark test: A cycle of spark at different voltages are generated in order to test the hardware/software behavior of the PS under this critical conditions.
Calibration: independent measurement of the voltage and current (PS and test-box). The Trip-time, the rump-up and rump-down are also calibrated.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

20. High Stress Test description I
I.N.F.N. Naples
The test-box consists of a custom rotating switch controlled by a step-to-step motor through a microcontroller (Microchip) .
Each position of the switch corresponds to an electrical contact placed on a PCB and positioned on a circle at a distance of 22,5o each others.
The motor needs 400 steps to make a complete turn corresponding to about 0.9o/step.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

21. High Stress Test description II
I.N.F.N. Naples
The micro-controller PIC 16F is used to:
controls the motor through a custom board housing a “power driver” used to generate the phases needs to control the motor.
drive the LCD monitor placed on the box and the manual control.
drive the communication through a serial port RS232 used to connect it to a PC.
control an internal ADC (10 bits) and drive a Programmable Gain Amplifier. It is used to measure the current provided by the PS at different full scale (1mA, 100 mA, 1mA).
Each position of the commutator is connected to:
a different resistive charge (10G, 5G, 1G, 100M, 9M, 6);
one of the four spark systems (10KV, 5KV, 2KV, short);
The spark system consists of two electrodes connected between the high voltage and the ground, placed at a fixed distance in order to generate sparks at a predetermined voltage.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

22. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
Ripple measurements
I.N.F.N. Naples
We are studying the noise and ripple of the HV and LV boards using a scope connected to a PC equipped with LabVIEW.
After a month we have not seen any unusual noise/events on both the boards.
The ripple peek to peek at load (f < 1 MHz) of the 2 HV channels is < 20 mV while for the 6 LV channels it is about 200 mv ???
The problem is present also when LV is OFF but mainframe is ON (could be a bad ground connection ?) is under study.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

23. Radiation & Magnetic Field
CAEN EASY project I
I.N.F.N. Naples
EASY +
DCS
OPC SERVER
CAN Bus based link
Ad-hoc protocol
Speed and reliability
No interoperability issues
Can work in hostile area
It seems to respect the
hardware and software
requirements made
by CMS but we need
a prototype to say YES
Standalone
EASY
3000
4000
Rack Mount
Radiation & Magnetic Field
Full integration in SY1527/SY2527
21 slots per crate
3 kW Maximum Output Power
Magnetic field capability: 2 kGauss
Expected rad.tol.: 5*1010 p/cm2 , 2*1011 n/cm2 ,15 kRad
Per channel:
Independent ON/OFF
Vmon (Connector and Load), Imon
Vset (Software or Hardware)
Programmable Trip, Sense wires
Status Signals
Imax per module (Hardware)
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

24. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
CAEN EASY project II
I.N.F.N. Naples
boards ready to be produced (on catalog)
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

25. CMS common LV solution proposal
I.N.F.N. Naples
In the 2002 the CMS collaboration decided to evaluated the possibility to have a common solution for the LV (and HV) system in order to minimize: costs, installation, software, spare, expertise and maintenance.
The idea has been enthusiastically accepted by the sub-detector unless HCAL.
CMS has contacted a lot of electronic companies asking them to propose a common LV solution for all the subsystems giving them some general requirement and all the requirement got from each sub-detector.
In the last CMS Electronic week (May 2003) companies have been invited to present a LV system for all the CMS subsystem.
Two companies; CAEN and WIENER presented two projects for LV (and HV)
The CAEN project, called EASY, is a natural evolution of the SASY 2000
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

26. 1 HV ch. per chamber 2 LV ch. per chamber The “final” HV & LV schema
I.N.F.N. Naples
Reduction of
HV 1020  480 ch
LV 1560  960 ch
1 HV ch. per chamber
2 LV ch. per chamber
SECTOR schema
6 FEBs / 2 bi-gaps
6+6+6 FEBs / 3 bi-gaps
1+1 HV
1 HV
2 LV
6+6 FEBs / 2 bi-gaps
12 LV channels HV channels
per wheel
TOT
gaps
408
2040 HV 96
480
FEBs
936
4680 LV
144
720
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

27. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
HV & LV system overview
I.N.F.N. Naples
Control Room
LV ch.
720
LV baords 60
EASY 20
HV ch.
480
HV boards 80 12
SY1527
HV-EASY
HV-EASY
Detector HV
distributor
1 in – 2 out HV
distributor
1 in – 2 out 3 4
RPC LV
RPC LV 2 5 1 6 12 7 11 8
RPC LV
RPC LV 10 9
HV 4-polar cable
LV cable
HV 10x4-polar cable
panel HV
panel HV
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

28. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
LV connections schema
I.N.F.N. Naples
60 LV boards placed in
20 crates (1 per balcony)
Power consumption:
board (12 ch.)  116 W
crate (3 boards.)  350 W
wheel (4 crates)  1.4 KW
Total  7.0 KW
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

29. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
HV: where we are
I.N.F.N. Naples
High Voltage (SY1527-EASY-A3012):
The power supply tender has been assigned to the CAEN in the 2004;
A complete prototype has been delivered in Dec 04 and has been tested in Naples using the RB3 chamber.
Board Delivery will begin in Sept 05…to Feb 06.
All HV cables will be assembled at the CPE. The cables for the first two sectors are ready
The multi-conductors cables has been delivered at CERN and will be sent at CPE to be assembled in Sept 2005;
The barrel HV distributors are in production;
The HV patch panels in the 2005 ?;
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

30. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
LV: where we are
I.N.F.N. Naples
Low Voltage (SY1527-EASY-A3009) :
The power supply tender has been assigned to the CAEN in the 2004;
A complete prototype has been delivered in Dec 04 and has been tested in Naples and then modified by the CAEN to reduce the noise (see next).
Delivery will begin in Sept 05…to Feb 06.
All HV cables will be assembled at the CPE.
Cable, connector and pins have been received.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

31. LV ripple Test Napoli feb 05
Noise ripple 01/05:
+/ ~ 10 mV (150 KHz)
+/GND ~ 1 V (150 KHz)
-/GND ~ 1 V (150 KHz)
EASY
CRATE
- +
mP GND
crate GND
shield
LV cable
Solutions proposed:
+/GND  C ~ 10 mF
mP GND / crate GND  C ~ 100 mF
better crate GND
sense reference connections
new connector
Same for the HV board
10 mt
Result 04/05:
+/ ~ 10 mV (150 KHz)
+-/GND ~ 30 mV (150 KHz)
Ana1+
Ana1 –
Dig1 +
Dig1 –
Ana2+
Ana2 –
Dig2 +
Dig2 -
RPC RB3
distrib.
shield
safety
GND
Ref. GND

32. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
Rack LV
From LV power supply with floating output
ALV1
AGND1
ALV
DLV1
DGND1
shielded cable
AGND
ALV2
AGND2
DLV
DLV2
DGND
DGND2
shield LV
distrib. board
4 pairs
IRON – MAGNET
safety ground
AGND
FEB 1
chip
chip
AGND
FEB
copper
strip
chip
kapton
Double Gap 2
AGND
DGND
Double Gap 1
Chamber metallic structure
AGND
chip
chip
FEB 6
HVReturn
Grounding
Schema
Copper 2
Copper 1
chamber GND
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

33. Barrel/Endcap HV and LV numbers HV LV
I.N.F.N. Naples HV
COST
Channel
SY1527
A3512
EASY
distrib
Barrel
480 1 80 12 30
500 K€
Endcap
432 72
472 K€
3500 Euro LV
COST
Channel
SY1527
A3009
EASY
distrib
Barrel
720 1 60 20
260 K€
Endcap
864 72
16-20
280 K€
3200 Euro
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

34. Barrel/Endcap HV and LV costs
I.N.F.N. Naples
Barrel
Hardware
Equipment
Cabling
TOT HV
300 K€
140 K€
60 K€
500 K€ LV
230 K€
14 K€
16 K€
260 K€
Endcap
Hardware
Equipment
Cabling
TOT HV
272 K€
140 K€
60 K€ ?
472 K€ LV
250 K€
14 K€
16 K€ ?
280 K€
The total cost of the HV & LV systems is 760 – 752 K€;
The HV-LV barrel cost increase (80 K€) is due to the hardware cost;
10% of the total cost is due to the cable installation.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

35. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
USC55 HV-LV barrel racks 8U
EASY
fan tary
heat exchange
HV distributor 2U
50 U
36 input ch.
48 output ch.
Total:
144 output ch.
144 input ch.
"full" crate schema
General Information
HV EASY board: 7 ch.
Full EASY crate: 42 ch.
EASY (6 out 7): 36 ch.
HV distributor:
32 input ch.
16 output ch.
Rack height tot: 56 U
turbine 4 U
air defl. 2 U
Rack available height 50 U
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

36. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
EASY
fan tary
heat exchange
HV distributor 2U
56U/
56 U
36 input ch.
48 output ch.
S1H02
turbine
air deflector 4U 8U
EASY
fan tary
heat exchange
HV distributor 2U
36 input ch.
48 output ch.
S1H03
turbine
air deflector 4U 8U
EASY
fan tary
heat exchange
HV distributor 2U
36 input ch.
48 output ch.
S1H04
turbine
air deflector 4U
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

37. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
S1H05 4U
turbine
Some numbers about this configuration:
3 “full” racks with:
4 EASY crates with 6 HV boards;
24 HV boards A3512;
9 HV distributors;
tot of 144 HV channels;
total height 56U (full).
1 “half” rack with:
2 SY1527 mainframes;
2 EASY crates with 4 boards;
3 HV distributors;
tot of 48 HV channels.
SY1527 HV 8U
SY1527 LV 8U
EASY
fan tary
heat exchange 8U
24 input ch.
HV distributor 2U
48 output ch.
42U/
56 U
EASY
fan tary
heat exchange 8U
24 input ch.
TOTAL numbers
14 EASY crates;
80 HV boards A3512;
480 HV channel;
30 HV distributors;
2 SY1527 mainframes. 2U
air deflector
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RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

38. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
RPC rack map from DB
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RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

39. HV-LV Rack composistion
4 EASY crate per rack (S1H );
9 HV distributors;
6 HV board A3012 per EASY crate;
Rack S1H06 with 2 Mainframes + 2 A3486
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RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

40. HV cable and connectors
I.N.F.N. Naples
The HV cable and connectors have been chosen and approved by CERN
2 high voltage pins to supply –12 kV
1 pin for signal return
insulating material
Polietilene HDPE (Eraclene Polimeri Europa (57%)
Masterbatch (GPO1246 Viba) (43%)
Metal cover connected to external chamber aluminum frame
ZAMA (UNI 3717 G-Zn A14 Cu1)
Suitable to sustain up to 15 kV
Cable characteristics:
According CERN safety instruction IS 23
Single conductor- = 0.16 mm
Conductor 20°C = 147 /Km
Core- = 3 mm
Screen wire-=0.2 mm (for 10 conductors)
Overall diameter = 8.4 mm (for 3 conductors)
Price: €/Km (for 10 Km)
Price: 24 Euro/couple pieces
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RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

41. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
LV connector and cable
I.N.F.N. Naples
The LV cable and connectors are under discussion
LV cable: 8 wires  outer diam. = 7.5 mm Price 1,00 Euro/m
12 wires  outer diam. = 8.5 mm Price 1,50 Euro/m
LV cable connector:
female 12 pins Molex Microfit-Fit 3,0 ( ) Price 3,49 Euro/5
female pins 20 AWG Molex Microfit-Fit 3,0 ( ) Price 10,37 Euro/100
LV RPC connector:
male 12 pins Molex Microfit-Fit 3,0 ( ) Price
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

42. LV and HV CAD cable design
I.N.F.N. Naples
Max LV/HV local cable lenght = 15 mt
Min LV/HV local cable lenght = 6 mt
Average lenght = 12 mt
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RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

43. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
HV & LV board test
I.N.F.N. Naples
Every HV and LV boards will be tested using “loading” box built in Naples.
We are still discussing about the place to test them (Naples or at CERN).
The test consists in a sequence of ramp-up and ramp-down followed by a 24 hours test at maximum load of every channels.
Test will be done automatically using a LabView program written in Naples by David Lomidze;
Board info and results will be stored in an ad-hoc mysql DB.
The board will not pass the test will be sent back to the CAEN.
We hope to finish our test in May 2006 and to begin the installation during the summer 2006.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

44. HV & LV board test in Naples
I.N.F.N. Naples
Test setup in Naples consists of: EASY crate + A3009 (LV) + ADC + A3012 (HV)
and 1 AC/DC for the 48 Volts (A3484) + 1 loading box for HV and 1 for LV
48 Volts
LV HV ADC
loading box
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RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

45. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
HV & LV board test
I.N.F.N. Naples
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RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

46. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
HV & LV database
I.N.F.N. Naples
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RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli

47. RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli
Conclusions
I.N.F.N. Naples
The HV and LV boards are now, after three interactions with CAEN, in the specification and are in production;
Chamber cables are in production (first 2 sectors);
Ready to produce the “long cable” (waiting for cut–length);
Distributors and patch panels are almost ready (mid 2006);
The systems will be installed during the summer 2006;
Still working on the 48 Volts AC/DC converter;
Reduced system will be test during the next year Cosmic Challenge;
Let me thanks Ranieri and Loddo for all the work done on the system before and with the Naples group.
18/09/2018
RPC Manufacturing Review - Pierluigi Paolucci - I.N.F.N. Napoli