EMC issues for cabling and racks layout design. (Belle II – Grounding) F.Arteche.

Slides:

Advertisements

Similar presentations

ELECTROMAGNETIC COMPATIBILITY Dr. Donald Church Senior Staff Engineer International Rectifier Automotive Systems November 17, 2005.

Advertisements

1 Designing for DVI General Applications Considerations.

EE4503 Electrical Systems Design

M.PEGORARO Grounding Workshop 24th Jan 08 DT GROUNDING & SHIELDING Presented by A. BENVENUTI.

Designing a EMC Compatible Electronic Meter using AD7755 a.

Input Transducers (Microphones).

Lecture 1: Safety and Protection. 1. A robot may not injure a human being or, through inaction, allow a human being to come to harm. 2. A robot must obey.

Lecture 101 Introduction to Energy Storage Elements: The Capacitor.

ESE – Andrew Rusek Applications of Computer Modeling in Electromagnetic Compatibility (EMC) Tests (Part1) P8. Field Pattern of Three Radiating.

NETWORK DESIGN Customer requirements Network topologies Cable choice Hardware TSB 75 TSB72.

EMC Technology Roadmapping: A Long-Term Strategy Marcel van Doorn Philips Applied Technologies EM&C Competence Center Eindhoven, The Netherlands, March.

PDS secondo le IEC n.

Lecture 101 Capacitors (5.1); Inductors (5.2); LC Combinations (5.3) Prof. Phillips March 7, 2003.

Chapter 8 Output Modules.

WHAT IS IN ELECTRICAL ENGINEERING?

EMC review for Belle II (Grounding & shielding plans) Sub-systems ( XXXXX)

Technician License Course Chapter 2 Radio and Electronics Fundamentals

Prof. David R. Jackson ECE Dept. Fall 2014 Notes 5 ECE 2317 Applied Electricity and Magnetism Notes prepared by the EM Group University of Houston 1.

Network Cabling and Wireless Network

Experimental Area Meeting V. Bobillier1 Good connection to earth (in many points) of every metallic parts to be installed in the cavern is very.

Layout Considerations of Non-Isolated Switching Mode Power Supply

ITAINNOVA TA: Scientific & Administrative issues Electromagnetic Compatibility Facility for electronics noise and grounding diagnostics (WP12 – Task 12.2)

Revised: Aug 1, EE4390 Microprocessors Lessons 29, 30 Welcome to the Real World!

Operational and Technical Requirements Rob Connatser Chief Instrument Project Engineer November 2014.

PROFIBUS wiring/installation can be done with:

1 Electronics & Signals Honolulu Community College Cisco Academy Training Center Semester 1 Version

PCB Layout Introduction

LECTURER PROF.Dr. DEMIR BAYKA AUTOMOTIVE ENGINEERING LABORATORY I.

PCB Layout Introduction

Integrated Grounding, Equipotential Bonding and Lightning Protection in Smart Grids and Smart Buildings – A Multi-Faced Approach Ladies and gentlemen,

Transmission Lines No. 1  Seattle Pacific University Transmission Lines Kevin Bolding Electrical Engineering Seattle Pacific University.

Bits (0s and 1s) need to be transmitted from one host to another. Each bit is placed on the cable as an electrical signal or pulse. On copper cable the.

Overview of the ATLAS Electromagnetic Compatibility Policy G. BLANCHOT CERN, CH-1211 Geneva 23, Switzerland 10th Workshop on Electronics.

IPC Power Distribution Considerations A predominately important factor that should be considered in the design of a printed board is power distribution.

Electromagnetic Compatibility Test for CMS Experiment. Authors C. Rivetta– Fermilab F. Arteche, F. Szoncso, - CERN.

BKLM RPC Signal & Ground Schematic Gerard Visser, Indiana University (for the barrel KLM team) 10th B2GM, 11/2011 magnet structure GND 7mm FOAM 3mm GLASS.

Grounding Guidelines Developed for LBNE

Pixel Endcap Power Distribution Phase 1 Upgrade Plans Fermilab, University of Mississippi, University of Iowa Lalith Perera University of Mississippi CMS.

Prof R T KennedyEMC & COMPLIANCE ENGINEERING 1 EET 422 EMC & COMPLIANCE ENGINEERING.

HF-Protection of Electronic Circuits Thomas Losert.

F. Arteche EMC issues for Tracker upgrade. 1 de 19 CMS / ATLAS Power working group Paris- France, 23 September 2009 OUTLINE 1. Introduction. 2. EMC strategy.

Programmable Logic Controllers

A common 400 Hz AC Power Supply Distribution System for CMS FEE. Authors C. Rivetta– Fermilab. F. Arteche, F. Szoncso, - CERN.

Compilation of Dis-/Advantages of DC-DC Conversion Schemes Power Task Force Meeting December 16 th, 2008 Katja Klein 1. Physikalisches Institut B RWTH.

Research activities at ITA for future accelerator M. C. Esteban.

F. Arteche, C.Esteban, (ITA) I.Vila(IFCA) Electronics integration studies for CMS tracker upgrade.

Pixel power R&D in Spain F. Arteche Phase II days Phase 2 pixel electronics meeting CERN - May 2015.

CABLING SYSTEM PROTECTION. Screening/Shielding  1 In the Signamax Cabling System for the efficient screening of the telecommunications systems, the screen.

Network Media. Copper, Optical, Fibre (Physical Layer Technologies) Introduction to Computer Networking.

Thermal Screen Grounding CERN - Dec. 10 th, 2003 Enzo Carrone The thermal screen grounding and the tracker: a scary concert Enzo Carrone.

Preliminary conducted noise test results for LV power supplies Bruno Allongue CERN-PH-ESS Fernando Arteche Imperial College – CERN 21 January 2005.

1 Fundamentals of EMC Mitigation Strategies John McCloskey NASA/GSFC Chief EMC Engineer Code 565 Building 23, room E

Noise propagation issues in complex power cables for HEP detectors M. Iglesias, I. Echeverria,F. Arteche 12 th Meeting of the Spanish Network for future.

Dr.F. Arteche EMC DEPFET Project: A general overview.

Dr. F.Arteche Instituto Tecnológico de Aragón (ITA) Belle II: Grounding and Electronics Integration Issues.

1 John McCloskey NASA/GSFC Chief EMC Engineer Code 565 Building 29, room Fundamentals of EMC Dipole Antenna.

PXD – DEPFET PS noise emission tests Mateo Iglesias Fernando Arteche.

F. Arteche EMC: Electronics system integration for HEP experiments (Grounding & Shielding)

CLOSED LOOP SPEED CONTROL OF DC MOTOR WITH PWM TECHNIQUE

EMC review for Belle II (Grounding & shielding plans) PXD system - July 2012 Dr. Fernando Arteche.

Noise & Grounding Andrei Nomerotski (U.Oxford) 17 July 2007.

Chapter 7 Transmission Media Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

IEEE NPEC SC2 Equipment Qualification Electromagnetic Compatibility Compliance Type Test-Design Considerations- Installation and Mitigation Standard/Guidance.

Chapter 7 Transmission Media

GlueX Electronics Review Jefferson Lab July 23-24, 2003

Electromagnetic Compatibility BHUKYA RAMESH NAIK 1.

Authors C. Rivetta– Fermilab. F. Arteche , F. Szoncso, - CERN

Open Rack Specification 2.1 Update

Transmission Media 1 INTRODUCTION 2 GUIDED MEDIA 3 UNGUIDED MEDIA 7.#

Presentation transcript:

EMC issues for cabling and racks layout design. (Belle II – Grounding) F.Arteche

Outline 1.Introduction 2.Cables 3.Racks 4.Future plans for grounding 5.Conclusions 1 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

1. Introduction CsI EM calorimeter:RPC μ & K L counter: scintillator + Si-PM (for end-caps) PI barrel / Endcap TOP+A-RICH SVD (Silicon Vertex Detector) Central Drift Chamber PXD (DEPFET), Solenoid 2 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan Complex EM enviroment

1. Introduction 3 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

1. Introduction There are two elements that play an important role in the electromagnetic noise level of any experiment: –Cables –Racks They may generated many EMC problems: –Cable radiation –Cable susceptibility –Malfunctions due to high electronics density The EMC effects of this type of elements may be decreased by design ( layout and connectivity) –It is only a recommendation (where is possible) 4 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

2. Cables Cables may be classified based on EMC cable category –Class 1 is for cables carrying very sensitive signals. C1A - Low-level analogue signals such as millivolt output transducers and radio receiver antennae. C1B - High-rate digital communications. –Class 2 is for cables carrying slightly sensitive signals, Ordinary analogue (e.g. 4-20mA, 0-10V, and signals under 1MHz), low-rate digital communications (e.g. RS422, RS485), and digital inputs and outputs (e.g. limit switches, encoders, control signals). –Class 3 is for cables carrying slightly interfering signals Low voltage AC distribution (< 1kV) or DC power (e.g. 48V telecomm's power), where these do not also power 'noisy' apparatus. –Class 4 is for cables carrying strongly interfering signals. This includes all the power inputs or outputs (to or from) adjustable motor drives, power converters; and their DC links, RF equipment. 5 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

2. Cables 6 de 17 Cables of different EMC categories should be laid separately wherever possible 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

2. Cables In case where minimum distance among cables in different categories cannot be obtained, cables may be separated by: –metallic sheets, cable ducts, screens The feed and return cables of a circuit shall be laid together. –Power cables and sensitive signal cables Cables should run as close as possible to conductive detector structure – minimize ground currents effects 7 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

2. Cables Corner areas of open cables conduits are the best areas against EMI phenomena –Close conduits are the best option Free conductors (or shields) must be connected to ground structure No minimum distance is required in the case of intersection at right angle 8 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

2. Cables In case screening cables are used, the screen should be well connected to reference plane or to metallic cage. 9 de 17 TYPE OF FIELD RANGE OF FREQUENCY EFFECTS WHEN ONE END OF THE SCREEN IS EARTHED EFFECTS WHEN AT LEAST BOTH ENDS OF THE SCREEN ARE EARTHED Electrical Field Ef<1 MHzGood Electrical Field Ef>1 MHzAlmost no shielding effects Good Magnetic Field Hf<1 MHzAlmost no shielding effects Bad Magnetic Field Hf>1 MHzAlmost no shielding effects Good 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

3. Racks Racks layout design may improve system performance against EMI phenomena The most important elements that play an important role in rack (cabinet) noise issues are: –Reference plane or structure –Cable routing inside the rack –Equipment distribution –Rack grounding and shielding connection. REFERENCE PLANE –It helps to control EMC phenomena associate to local PS, filtering and electronics. –Walls or rack doors may used as REF. plane 10 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

3. Racks Rack layout is important - Example 11 de17 Rack Rack unit 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

3. Racks Inside rack cabinets cables may be split in 4 categories: –A - Power lines (DC-DC mainly) –B - LV ac lines (power mains),relays, contactors,.. –C2- Sensitive power and electronics, low digital communications –C1- Sensitive lines (analogue signals, output transducers, Ethernet cables, high rate communications) It is recommended to keep certain distance among cables categories. 12 de17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

3. Racks Unshielded cable bundles they should be carefully arrange (multiple return cables) Cable routing always as close as possible to metallic structures and ground references. Conductors carrying power or signals should not go too close to the edge of cabinet or rack structure. 13 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

3. Racks PCB connection to reference ground should be carefully designed Filter or cable shield should be well connected to cabinet to minimize EMC effects - Entrance Cabinet doors has to ensure the continuity of the cabinet. –Copper braid –This is very important for shielded cabinets 14 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

4. Future meetings Grounding sessions have been a very good opportunity to exchange information and experience among detectors. –We have to continue with them. It is planned to have a new big grounding session in the next B2GM – July at VPI,USA –A grounding review Main goal: –Continue system integration –Fix the project status - Review A common structure of the grounding status will be prepared by each sub-detector –We can keep the template used in the past 15 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan

4. Future meetings The suggested structure may cover the following aspects: –Outline of the grounding strategy Information about current or previous grounding topology –Design approach Implementation aspects –Emission and susceptibility issues. Analysis of the main noise sources and most susceptible components. –Identification & test plans –Shielding aspects, such as cabling layout connections and characteristics, are included in this point. –Conclusions and a summary of relevant results exposed. The grounding web-page (not finish yet) will be operational for the meeting (earlier) –Exchange information 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan 16 de 17

5. Conclusions Noise issues associated with cabling and racks may be decreased by layout Attention should be paid in cable and rack layout (small details will help) –It costs nothing – small details Good cable classification and rack distribution will help –Power and noise level –Proper grounding connections A new grounding session is planned for the next B2GM meeting – VPI, USA 17 de 17 14th Open Meeting of the Belle II Collaboration March 4 th -7 th, 2013, KEK, Japan