The electro-optical cabling system for the NEMO Phase-2 tower Antonio D’Amico INFN - LNS.

Slides:

Advertisements

Similar presentations

Amphenol Outdoor Connectors

Advertisements

© DIAMOND SA / / 1 Alberino CRA Alberino fixing system for modular constructions within industrial Mennekes housing.

Rope & Cable management A vertical electro-optical backbone cable for KM3NeT Gertjan Mul On behalf of the km3net collaboration Nikhef.

VLNvT workshop Amsterdam October 5-8th 2003 P. Lamare SACLAY DSM/DAPNIA Experience with electro-optic cable Wet mateable connection.

Integration of Cavities and Coupling Coil Modules Steve Virostek Lawrence Berkeley National Laboratory MICE Collaboration Meeting March 28 – April 1, 2004.

Optical Fiber Testing Paul Minko EE 566 Oct. 22, 2003.

AMS-02 tracker mechanics status of assembly and integration Inner tracker integration completion: - Assembly and cabling - Temperature and magnetic field.

MICE modules interface proposal FAC module Phone meeting Edgar Black IIT 2/13/2004.

Chapter 10 Optical fiber measuring instruments and testing single-mode fiber networks.

1 Fiber Optic Measurement Technique Piotr Turowicz Poznan Supercomputing and Networking Center Training Session Kiev 9-10 October.

1 Fiber Optics FIBER OPTIC PATCH PANELS. 2 Fiber Optics Just like our copper cable plant the fiber cable plant incorporates many of the same hardware.

Amsterdam October 2003 M. Sedita VLVnT Installation and Maintenance of the submarine network The Maintenance aspect present some difficult as their.

OPTICAL TIME DOMAIN REFLECTOMETER (OTDR)

Installation and testing

Mario MUSUMECI VLV T workshop Mechanics parallel session Critique Of ANTARES MECHANICS, S.CUNEO Analisys of mechanics ideas or NEMO, M.MUSUMECI R. OCCHIPINTI.

1 Cryostat assembly, integration and commissioning procedures M.Olcese Version: 07 May 2008.

Deep-sea neutrino telescopes Prof. dr. Maarten de Jong Nikhef / Leiden University.

Optical Fiber Connections joints and couplers

High Sensitivity Smoke Detection

GLAST LAT ProjectDOE/NASA Mechanical Systems Peer Review, March 27, 2003 Document: LAT-PR-0XXXX Section 5.1 Grid Box Design 1 GLAST Large Area Telescope:

Stefano russo Universita’ di Napoli Federico II & INFN Km3Net meeting Pylos 16–19/4/2007 The NEMO DAQ electronics: Actual characteristics and new features.

A sensor architecture for neutrino telescopes on behalf of the KM3NeT consortium Els de Wolf Thank you, Claudio!

25 km E offshore Catania 2000 m depth TSS Frame Buoy Junction Box e.o. connection e.o. cable from shore Shore laboratory, Port of Catania e.o. cable.

09/03/2010 ADO-PO section meeting Beam Pipe Extraction/Insertion R. Vuillermet.

Maintenance of the ANTARES deep-sea neutrino telescope 1 Marco Circella --- INFN Bari on behalf of the ANTARES Collaboration.

A for Military Ships August What is A? A is a system of: –tube assemblies –tube connectors –tube management closures –fibre bundles –fibre management.

CMS ECAL End Cap Meeting CERN 18 Oct to 22 Oct ECAL End Cap High Voltage and Fibre Optic Monitoring Systems Progress. Progress on High Voltage and.

Conceptual Design Requirements for FIRE John A. Schmidt FIRE PVR March 31, 2004.

Acoustic Calibration for the KM3NeT Pre-Production Module Alexander Enzenhöfer on behalf of the KM3NeT consortium VLV T 2011 Erlangen, –

The KM3NeT consortium ( - supported through the European Union's 6th framework programme in a 3-year Design Study - aims at the construction.

WET CONNECTION TOOL Concept validation. 14/10/2009Stéphan BEURTHEY-CPPM Underwater connections (1/3) Acoustics: no power and low data rate; Acoustics:

VLVnT11 - Erlangen 12-14/10/ Giorgio Cacopardo NEMO Phase2 mechanical design G. Cacopardo on behalf of NEMO collaboration.

Mechanical design of the Pre-Production Detector Unit Model of KM3NeT Mario MUSUMECI and Riccardo PAPALEO KM3NeT PP DU subgroup coordinators on behalf.

VLV T – Workshop 2003 Read Out and Data Transmission Working Group Synchronous Data Transmission Protocol for NEMO experiment.

A2-A5: The drawing has been revised (minor changes), the bid has been approved by INFN management and the invitation letter to the companies will be sent.

Vessel dimensions GTK assembly carrier Electrical connections Cooling pipes integration Vessel alignment with the beam Next steps Conclusion 3/23/20102electro-mechanical.

Eric Vigeolas, July the 3 rd Status The IBL detector construction already started and the components assembly (flex, modules, stave loagin) will.

© 2007 Cisco Systems, Inc. All rights reserved.Cisco Public ITE PC v4.0 Chapter 1 1 Planning a Network Upgrade Working at a Small-to-Medium Business or.

F. Simeone – INFN, Sez. Roma1 RICAP07 Conference, Rome June 2007 Data taking system for NEMO experiment RICAP07.

Status and Advances on the Acoustic Positioning System for KM3NeT Giuseppina Larosa, IGIC-UPV KM3NeT General Meeting, Nikhef 28-31/03/2011.

Optical performance measurements of various fibre connections

The sector of the Antares line to be deployed in the NEMO site Davide Piombo – INFN sez. Genova

1 Motivations KM3Net VEOC Based on developments on solid cable at NEMO and Antares project and proto cable of Seacon. Optimizing properties like; flexibility.

Wet Demonstrator Objectives. 2 A Brief History Functional Requirements First DraftJuly 2014 Wet Demonstrator Scope First DraftJuly 2014 Singapore Workshop.

05/07/2010P. LamareBackbone dry solution Dry backbone requirements.

Rosanna Cocimano for the NEMO collaboration VLV T08, Toulon, France April 2008 Rosanna Cocimano for the NEMO Collaboration A comparison of AC and.

Rosanna Cocimano Amsterdam, 5-6 July 2010KM3NeT WPF/L General Meeting Rosanna Cocimano INFN LNS Power plan for detector layout Presented in TDR.

M. Circella – ANTARES connectionINFN Comm. II, 5/6/2008 The ANTARES Connection Marco Circella --- INFN Bari 1.

M. Circella, INFN Bari Time-calibration in NEMO VLVnT08 Time calibration in NEMO M. Circella, INFN Bari Time calibration The NEMO Phase 1&2 towers Time.

KM3NeT-Italy Collaboration meeting 27/11/2014 Sistema di trasmissione dati su fibra ottica: Tower Sara Pulvirenti.

KM3NeT WPF/L NIKHEF- MECABAR 1 A.Cosquer on behalf of the KM3NeT consortium MECABAR PROJECT PLAN 1- Context 2- 3D views and responsibilities 3-

Mechanical design of the Pre-Production Detector Unit Model of KM3NeT Mario MUSUMECI and Riccardo PAPALEO KM3NeT PP DU subgroup coordinators.

WP F/L Detection Unit Mechanical Structure and Deployment R. Papaleo 130/03/2011.

Status of the NEMO tower validation Integration Tests Improvements Deployment program M.Anghinolfi- km3-day meeting )

KM3NET-IT Tower Power System Rosanna Cocimano for KM3NET-IT Power Group 26 november

Electronic department 5/7 July 2010, KM3NeT meeting at Nikhef - Mar van der Hoek et.al. Status and experiences with oil-filled Pressure Balanced backbone.

LIDO Meeting - Catania 13/01/ Giorgio Cacopardo Arrangement of PCB in LIDO E-POd.

EC: 7 DISK concept Preliminary considerations

A DWDM link for Real-Time data acquisition systems

ATLAS Internal ID Service Integration

Deep-sea neutrino telescopes

Write-up and Definitions for Cost Model

LBNF CAD models, Drawings and Component list

Update of MVD services and requests

Data transport architecture over fiber and/or copper

Junction Boxes for KM3NeT

Commissioning and Testing the LHC Beam Interlock System

Safety, reliability and maintainability

CrystaLatchTM 1x1,1x2, Solid-State Fiberoptic Switch

Michail Anastasopoulos Lead Detector – Design Engineer

Presentation transcript:

The electro-optical cabling system for the NEMO Phase-2 tower Antonio D’Amico INFN - LNS

Antonio D’Amico INFN - LNS VLVnT 08 Talk layout Design criteria Detector structure Interfaces Cabling structure Serviced “Users”

Antonio D’Amico INFN - LNS VLVnT 08 Design criteria Fault tolerance Connectors can be Single point failures Prefer penetrators Reduce number of interfaces Modularity Adopt easy to upgrade layouts Simplicity Small number of interfaces Ease of assembly Prefer connectors Prefer light weight cables Ease of management Adopt easy to repair layouts Adopt easy to test layouts Costs Less connectors (especially optical connectors) Prefer penetrators Use standard cables

Antonio D’Amico INFN - LNS VLVnT 08 Modular structure  Beams (storeys) to host the instrumentation and Optical Module  Retention ropes to configure the tower in the correct geometry  Buoy to pull up the beams and keep the tower full opened Detector structure The ropes can support the backbone cabling The backbone:  is not exposed to stresses  should be light in seawater  should be flexible The floor cabling can be laid inside the beams The floor cabling  is protected by the beam  should be flexible Standard cables are suitable for this detector

Antonio D’Amico INFN - LNS VLVnT 08 Breakdown Structure - Interfaces Tower cabling Base cabling Backbone cabling Floor cabling JBox Jumper Acoustic Beacon Optical Modules Instruments Hydrophones JOINT JOINT

Antonio D’Amico INFN - LNS VLVnT 08 Design Optimization  Full Tower Backbone needs to be MODULAR in order to SIMPLIFY THE INTEGRATION PROCEDURES and to attain EASE OF HANDLING  BREAKOUT Re-Design  New BREAKOUTS designed like submarine JOINTS  ADD&DROP DWDM OPTICAL FILTERS relocated into the floor pressure vessel  ELECTRO-OPTICAL CONNECTORS REMOVED (->cost reduction and increased reliability)  Only ELECTRIC CONNECTORS at user’s interfaces P P 1 C 4 3 C P P P P 2 C C LC P Tower base module P F base Prototype TOWER

Antonio D’Amico INFN - LNS VLVnT 08 Backbone - Modular Layout POD 15 BJ... POD 14 BJ POD 0 BJ  MODULARITY obtained by means of field mountable JOINTS  No optical connectors along the optical path from detector base to floor Laser into the POD  JOINTS on each floor are protected inside the storey beams o OM BASE POD BJ

Antonio D’Amico INFN - LNS VLVnT 08 Backbone - Electro-Optical JOINTS PP Field mountable submarine JOINT Functions:  HOST the FIBRE FUSION SPLICES  HOST the ELECTRICAL JOINTS Interfaces:  PENETRATORS (P) to interface the JOINT with the BACKBONE CABLE  EASE OF MANAGEMENT during TESTING (connectorized fibers)  EASE OF OPTICAL TESTING after FINAL INTEGRATION (fusion splices replacing the connectors) 350 bar 1 bar Pressure Vessel POD upper floor link lower floor link JOINT

Antonio D’Amico INFN - LNS VLVnT 08 Backbone and Floor Pressure Vessel F F BJ upper floor link lower floor link 350 bar 1 bar 350 bar Pressure Vessel P P PP main features FEEDTROUGH (F) on plastic vessel wall ELECTRICAL CONNECTOR (C) to route electrical link separately OPTICAL PENETRATORS (P) on Pressure Vessel Plastic Vessel POD C C

Antonio D’Amico INFN - LNS VLVnT 08 Floor Cabling - POD F F  backbone P P 2 C F OM2 OM1 H1 C DC/DC BJ OM Pressur e Vessel Plastic Vessel Instrument Hydrophones upper floor lower floor F F F F F F P P main features  point to point connection from Pressure Vessel to Users (OM, hydrophones and instruments) -> ease of maintainance and increased realiability  FEEDTROUGH (F) on plastic vessel wall  ELECTRICAL CONNECTOR (C) on pressure vessel cap and on users side (OM, hydrophones and instruments)  OPTICAL PENETRATORS (P) on pressure vessel cap for backbone fibers input/output 350 bar 1 bar 350 bar C C C C C C C C C

Antonio D’Amico INFN - LNS VLVnT 08 Conclusions In order to have an ease to assemble system:  Position connectors at sub-systems interfaces  it allows to have few connectors  it reduces costs.  Use light weight cables  Position connectors at users interfaces In order to minimize the Insertion Loss and Back Reflection:  few connectors  it reduces costs. Sub-systems must be testable in pressure tank:  Prefer penetrators for an easy interface with pressure tank cap or flanges.  Prefer penetrators on the backbone cable in order to have no optical “breaks” along the path  OTDR testing can be more accurate and repeatable.