Main I&C/Electromagnetic Compatibility: Difference between revisions

From EPRI Nuclear I&C Wiki
Jump to navigation Jump to search
No edit summary
No edit summary
 
(2 intermediate revisions by the same user not shown)
Line 1: Line 1:
{{DISPLAYTITLE: Electromagnetic Interference and Compatibility}}
{{DISPLAYTITLE: Electromagnetic Interference and Compatibility}}[[File:EMC_topics1.jpg|frameless|right|600px|EPRI EMI & EMC research topical areas]]
[[#Record of Revisions|'''''Revision 0''''']]
[[#Record of Revisions|'''''Revision 0''''']]


Electromagnetic Interference (EMI) manifests as malfunctions at the component, equipment, subsystem and system level. Generally, EMI is an electrical disturbance from either a natural phenomenon (lightning, Electrostatic Discharge (ESD), etc.) or an electrical or electronic equipment that causes an undesired response (malfunction) in other equipment. These malfunctions can result in time consuming delays for investigation and troubleshooting to implement needed corrections. Electromagnetic Compatibility (EMC) looks at controlling those disturbances using installation and other EMI and Radiofrequency Interference (RFI) reducing techniques that are implemented early in the design and installation of the equipment or system.
Electromagnetic signals can produce malfunctions at the component, equipment, subsystem and system level if not properly controlled and compatible with their environment. These disturbances created by either natural (lightning, Electrostatic Discharge (ESD), etc.) or man-made sources (radio transmissions) present I&C design, maintenance, and reliability challenges when electromagnetic interference (EMI) affects either safety or non-safety and important to power production functions. These malfunctions can result in time consuming delays, forced outages, or other severe consequences. Hence, electromagnetic Compatibility (EMC) and the practices that promote compatibility play an important role in managing the I&C equipment lifecycle and promoting equipment reliability.  


This Wiki introduces readers to existing EPRI EMC guidance related to the following topics:
The following Wiki provides an outline of existing EPRI EMC guidance related to the following topics:


[[File:EMC_topics1.jpg|frameless|none|700px|EPRI EMI & EMC research topical areas]]
=Background=
System and component EMC refers to the equipment’s ability to function, as designed, without adverse degradation or failure due to interference sources operating in its intended environment. EMC also refers to the equipment’s ability to function without adversely affecting other equipment connected to or located in that environment.


Emissions, whether deliberate or unintended, are electromagnetic energy generated by one or more radiating or conducting sources. This energy is released into the ambient environment which can create EMI. EMI can degrade or cause failures of equipment in the surrounding area or within a device or its enclosure.


=Background=
EMC assessment is a process that involves:
EMC received renewed attention in the early 1990s when nuclear power plants started replacing obsolete analog I&C systems with newer digital systems. Little guidance was available then on EMC for nuclear plants, and EPRI addressed the issue by publishing the =Handbook for Electromagnetic Compatibility of Digital Equipment in Power Plants and a series of iterations the [[#TR-102323_Guidelines_for_Electromagnetic_Compatibility_Testing_of_Power_Plant_Equipment_versions_access_table|Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment (aka TR-102323)]] that reflected the increasing knowledge base and evolution of testing standards.


One issue of special note in early versions of the EMC testing guideline is the treatment of CS114, a high-frequency conducted susceptibility test that has proven particularly problematic for most equipment. The CS114 test levels recommended in earlier revisions of the EPRI EMC testing guideline were based on plant data acquired by EPRI in the early 1990s. The results of the reevaluation published in 2003 and 2007 EPRI reports indicated that the early data was misapplied, and less conservative test levels have been proposed in the revisions TR-102323 EMC testing guideline since 2008.
* Understanding anticipated continuous-wave and transient emissions in the environment where equipment will be installed
* Selecting a device or system that is intended to be compatible with the environment
* Evaluating the immunity of the device or system to ensure it will perform reliably as designed when exposed to expected electromagnetic emissions
* Evaluating the emissions of the device or system to ensure it does not exceed acceptable thresholds thus creating the potential to cause interference with existing equipment local to the point of installation
* Installing and maintaining the system as intended for an acceptable level of EMC


The other EMC issue identified in 2006 was the increasing use of cell phones and later wireless technologies, EPRI continues to work on assessments of new wireless devices susceptible of introducing electromagnetic interferences in the plant environment and incorporating the results of those assessments into newer versions of the TR-102323.
Reasonable assurance of EMC can be achieved by satisfying each of the bullets above.


Finally, EPRI published in 2023 the Electromagnetic Compatibility Assessment Methodology (EMCAM) a risk-informed EMC assessment and control method allocation process for Digital I&C equipment, designed for use within the [[Main I&C/Digital_Systems_Engineering_Framework|EPRI Digital Systems Engineering Framework]].
=EPRI Guidance and Training on EMC Fundamentals=


=Fundamentals=
==EMC Handbook==
The two volumes of the Handbook for Electromagnetic Compatibility of Digital Equipment in Power Plants were published in 1994 and are since 2008 publicly available. The handbook explains the fundamentals of electromagnetic compatibility and provides guidelines for ensuring the electromagnetic compatibility of digital equipment in power plants. The handbook is applicable to digital equipment being installed in all types of power plants.
EPRI's ''Handbook for Electromagnetic Compatibility of Digital Equipment in Power Plants'' is a dual volume publication that is available to the public. The handbook explains the fundamentals of electromagnetic compatibility and provides guidelines for ensuring the electromagnetic compatibility of digital equipment in power plants. The handbook is applicable to digital equipment being installed in all types of power plants.
* [https://www.epri.com/research/products/TR-102400-V1 Volume 1] - Fundamentals of EMI Control: presents a comprehensive and theoretical discussion of the fundamentals of EMI control. This volume is a reference to assist the reader in answering questions encountered while on the road to fully understand and prevent potential EMI problems.
* [https://www.epri.com/research/products/TR-102400-V1 Volume 1] - Fundamentals of EMI Control: presents a comprehensive and theoretical discussion of the fundamentals of EMI control. This volume is a reference to assist the reader in answering questions encountered and to fully understand potential and existing EMI problems.
* [https://www.epri.com/research/products/TR-102400-V2 Volume 2] - Implementation Guide for EMI Control: presents a practical implementation guide for EMI control, beginning with design and procurement through testing and installation; it also includes information on operation and maintenance.
* [https://www.epri.com/research/products/TR-102400-V2 Volume 2] - Implementation Guide for EMI Control: presents a practical implementation guide for EMI control, beginning with design and procurement through testing and installation; it also includes information on operation and maintenance.


==Training Materials==
==Training Materials==
EPRI provides training on EMI & EMC fundamentals, browse [https://www.epri.com/training/courses?sectorLTN=Nuclear EPRI Training and Development Platform] for future training opportunities.
EPRI provides training on EMI & EMC fundamentals and its guidance documents addressing the subject, browse [https://www.epri.com/training/courses?sectorLTN=Nuclear EPRI Training and Development Platform] for future guided training opportunities.


For self-paced learning opportunities on the topic, review:
For self-paced learning opportunities on the topic, review:
*  [https://www.epri.com/research/products/000000003002013818 Engineering Technical Training Module (ETTM) – EMI and RFI Noise Analysis]: a computer based training course updated in 2018 that allows students to learn the types and characteristics of electrical disturbances found in a power plant environment.
* [https://www.epri.com/training/courses/69a800f5-7452-44e5-acfa-9b8612a30245 Engineering Technical Training Module (ETTM) - EMI and RFI Noise Analysis, Version 1.0]: a computer based training course that provides training for power plant engineers on the types and characteristics of electrical disturbances found in a power plant environment.  
* [https://www.epri.com/training/courses/69a800f5-7452-44e5-acfa-9b8612a30245 Engineering Technical Training Module (ETTM) - EMI and RFI Noise Analysis, Version 1.0]: a computer based training course that provides training for power plant engineers on the types and characteristics of electrical disturbances found in a power plant environment.  
* [https://www.epri.com/research/products/000000003002018372 EMI Qualification of Digital Equipment Upgrades - Revision 2, Version 3]: a computer based training course that presents the recommended generic EMI susceptibility and emissions test levels for use in establishing equipment EMC for nuclear power plant applications.
* [https://www.epri.com/training/courses/91da5d5e-3b11-4dcf-bf0f-d726872ae716 EMI Qualification of Digital Equipment Upgrades - Revision 2, Version 3]: a computer based training course that presents the recommended generic EMI susceptibility and emissions test levels for use in establishing equipment EMC for nuclear power plant applications.
* An EMC fundamentals training is being developed and will be available soon.


=EMC Testing and Control Guidance=
An instructor-led EMC fundamentals training is in development and will be available from EPRI in the future.
As discussed in the [[#Background| background]] the EMI & EMC knowledge increased in the industry with the practical experience and research completed and this was reflected in the different iterations on the Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment (aka TR-102323). The  [[#TR-102323 Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment versions access table|TR-102323 table]] below describes the main changes and provides links for access in [https://www.epri.com/ EPRI website].


In addition to continuing with the evolution of the testing guidance, EPRI has developed a risk informed methodology that integrates with the [http://dcx-webwik-p01.epri.com:5005/MainIC/Digital_Systems_Engineering_Framework Digital Systems Engineering Framework] as the risk-informed testing and control method allocation process for EMC. The [[#EMCAM - A risk-informed approach to EMC|EMCAM section ]] below describes the main changes and provides links for access tp its most current version in [https://www.epri.com/ EPRI website].
=EPRI's Guidance on EMC Testing and Control Method Allocation=
EPRI’s EMI testing and control method allocation guidance resides in two flagship products that are further described (motivations and evolution) in the following sections:
* Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment (TR-102323), and   
* Electromagnetic Compatibility Assessment Methodology (EMCAM)


==TR-102323 Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment versions access table==
==Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment (TR-102323)==
 
The initial version of EPRI Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment, referred to as TR-102323, was focused on stabilizing the licensing process associated with U.S. nuclear plant digital I&C equipment upgrades. The initial publication addressed the following fundamental concepts:
 
* Recommended electromagnetic and radio interference (EMI/RFI) susceptibility testing levels
* Recommended equipment emissions testing levels
* Recommended design and installation practices
 
Future revisions to TR-102323 up to and including the current revision 5 build on those fundamental concepts. See [[#TR-102323 versions access table|TR-102323 table]] below for a list of versions of this guidance with descriptions of the main changes between them and links for access in [https://www.epri.com/ EPRI website].
 
The TR-102323 methodology and recommended testing limits accomplish the following two objectives:
# Ensure equipment susceptibility limits bound measured plant emissions levels by a margin of at least 8 dB or more (see ''Bounding Plant Emissions'' figure below). The 8 dB susceptibility margin was required to obtain U.S. Nuclear Regulatory Commission (NRC) endorsement for “Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment” Revision 1 to EPRI TR-102323.
# Establish one set of bounding equipment susceptibility and emissions testing limits to qualify equipment one-time for use in any commercial power plant in any location.
[[File:Emissions levels.jpg|frameless|center|350px|Bounding Plant Emissions (Source: TR-102323 Appendix N)]]
 
 
In addition to recommending susceptibility limits that support one-time qualification testing that bounds plant emissions, TR-102323 also provides a graded approach for testing systems based on safety classification and the potential impact to plant operations. Table 5-1 ''Testing Applicability'' on TR-102323,  documents a complete suite of susceptibility type tests applicable for safety related applications, recommends the same suite of susceptibility type tests for applications that are non-safety related and important to power production, and provides optional susceptibility testing guidance for other non-safety related applications. Table 5-1 also documents applicable high-frequency conducted and radiated equipment emissions testing for each of the aforementioned applications.
This provides assurance that new equipment installed in a facility, regardless of its safety classification, will not interfere with safety-related equipment.
 
The TR-102323 methodology provides high assurance of EMC and attempts to reduce the need for subsequent re-qualification based on a modified use case. While this can eliminate the need to repeat susceptibility or emissions testing to different testing levels for each application, qualification to lower susceptibility or higher emissions limits may be technically acceptable and also reduce qualification costs in certain applications.
 
 
===TR-102323 versions access table===
{| class="wikitable" style="margin:left"
{| class="wikitable" style="margin:left"
|+  
|+  
|-
|-
! Revision # !! Publication year !! Notes  
! Revision # !! Publication year !! Revision notes  
|-
|-
| [https://www.epri.com/research/products/000000003002015757 '''Revision 5'''] and the [ '''Errata version'''] || 2019 & 2024 || The latest revision, incorporates all learnings from past versions and contains in the appendixes the technical bases for the changes. It also adds additional guidance and clarification to various sections of the document based on current events and issues experienced by the nuclear power industry. This includes the addition of an example exclusion zone calculation with clarification supporting each equation recommended for use by the guideline, arc welding EMI suppression guidance, adjustable and variable frequency speed drives EMI suppression guidance, lighting system EMI suppression guidance, wireless emissions control guidance, a summary of lessons learned and operating experience from nuclear industry related EMI events.
| [https://www.epri.com/research/products/000000003002015757 '''Revision 5'''] || style="text-align:center;" | 2024 (Errata)
----
2019
|| The latest revision, incorporates all learnings from past versions and contains in the appendixes the technical bases for the changes. It also adds additional guidance and clarification to various sections of the document based on current events and issues experienced by the nuclear power industry. This includes the addition of an example exclusion zone calculation with clarification supporting each equation recommended for use by the guideline, arc welding EMI suppression guidance, adjustable and variable frequency speed drives EMI suppression guidance, lighting system EMI suppression guidance, wireless emissions control guidance, a summary of lessons learned and operating experience from nuclear industry related EMI events.
The Errata version corrects an issue in the heading row for Table K-1, the column labels for Low-Frequency and High-Frequency under Emission Test for Radiated were transposed.  
|-
|-
| [https://www.epri.com/research/products/000000003002000528 '''Revision 4'''] || 2013 || This revision of the EPRI guidance made better use than previous ones of EMC testing standards commonly used by equipment vendors and suppliers and generally reduced differences with the recommendations of NRC Regulatory Guide 1.180, Revision 1. Where differences remained, the bases for the Revision 4 position were provided. One issue of special note in Revision 4 is its treatment of CS114. The CS114 test levels recommended in previous revisions of this report and in Regulatory Guide 1.180, Revision 1, were based on plant data acquired by EPRI in the early 1990s. The latest results indicate that the early data was misapplied, and less conservative test levels were recommended.
| [https://www.epri.com/research/products/000000003002000528 '''Revision 4'''] || style="text-align:center;" | 2020 (Errata)
----
2013
|| This revision of the EPRI guidance made better use than previous ones of EMC testing standards commonly used by equipment vendors and suppliers and generally reduced differences with the recommendations of NRC Regulatory Guide 1.180, Revision 1. Where differences remained, the bases for the Revision 4 position were provided. One issue of special note in Revision 4 is its treatment of CS114. The CS114 test levels recommended in previous revisions of this report and in Regulatory Guide 1.180, Revision 1, were based on plant data acquired by EPRI in the early 1990s. The latest results indicate that the early data was misapplied, and less conservative test levels were recommended.
The Errata version corrects a discrepancy on the RS103 test frequency range appearing in Chapter 5 and on MIL-STD-461G and the one appearing in Appendix K.
|-
|-
| '''Revision 3''' || 2004 || Not available on EPRI website, revision 3 incorporated the results of the 2003 reevaluation of the conducted susceptibility limits and proposed less conservative test levels.
| '''Revision 3''' || style="text-align:center;" | 2004 || Not available on EPRI website, revision 3 incorporated the results of the 2003 reevaluation of the conducted susceptibility limits and proposed less conservative test levels.
|-
|-
| [https://www.epri.com/research/products/000000000001000603 '''Revision 2'''] || 2000 || This version revised the limits to reduce excessive conservatism, based on plant operating experience since the first version of the guide was released and broader frequency ranges to accommodate newer telecommunication devices.
| [https://www.epri.com/research/products/000000000001000603 '''Revision 2'''] || style="text-align:center;" | 2000 || This version revised the limits to reduce excessive conservatism, based on plant operating experience since the first version of the guide was released and broader frequency ranges to accommodate newer telecommunication devices.
|-
|-
| [https://www.epri.com/research/products/TR-102323-R1 '''Revision 1'''] || 1997 ||  Revision 1 reflected modifications to the original document.
| [https://www.epri.com/research/products/TR-102323-R1 '''Revision 1'''] || style="text-align:center;" | 1997 ||  Conditional on incorporation of a number of clarifications and publication of a revised report, the NRC issued a Safety Evaluation Report in April 1996 endorsing the revised report (the future revision 1). Since revision 1 was published, the TR-102323 became a de facto standard within the U.S. nuclear industry.
NOTE: The SER report has been maintained in the appendixes of the subsequent revisions of this guidance.
|-
|-
| '''Revision 0''' || 1994 || Not available on EPRI website, this first issue received NRC approval through a safety evaluation report (SER) in 1996 and became a de facto standard within the U.S. nuclear industry. The SER report has been maintained in the appendixes of the subsequent revisions of this guidance.
| '''Revision 0''' || style="text-align:center;" | 1994 || Not available on EPRI website, this first issue and was submitted to the NRC for revision.  
|-
|-
|}
|}


==EMCAM - A risk-informed approach to EMC==
==Electromagnetic Compatibility Assessment Methodology (EMCAM)==
The [https://www.epri.com/research/products/000000003002023743 Electromagnetic Compatibility Assessment Methodology (EMCAM)] is a risk-informed I&C equipment assessment and control method allocation process designed as an element of the [http://dcx-webwik-p01.epri.com:5005/MainIC/Digital_Systems_Engineering_Framework Digital Systems Engineering Framework] to:
 
* remove conservatism during equipment assessment (where acceptable) for a given application and
While TR-102323 supports a graded approach based on safety classification, it does not consider risk associated with different system use cases and applications. This is the intent of the [https://www.epri.com/research/products/000000003002023743 Electromagnetic Compatibility Assessment Methodology (EMCAM)]. It provides risk-informed guidance for equipment EMC qualification and control method allocation.
* tailor the testing scope and level and control method allocation for a given application.  
EMCAM is an alternate approach for assessing electromagnetic compatibility for a facility change and is not intended to replace the TR-102323 methodology. The two methods are compatible, and EMCAM does not invalidate any legacy equipment EMC qualification testing results.
This proposed method can potentially reduce testing costs and provide a more flexible decision-making during:
EMCAM is intended to complement the [[Main I&C/Digital_Systems_Engineering_Framework#Digital Engineering Guide (DEG) | EPRI Digital Engineering Guide (DEG)]] in the conceptual or detailed design phase of an I&C project.
* testing specification and assessment, and
The methodology evaluates EMC testing performance and control method allocation in new or modified I&C equipment designs using facility risk (e.g., impact to CDF) and application (e.g., installation environment classification) insights. Using the process requires either:
* allocation of additional electromagnetic interference (EMI) controls.  
* a HAZCADS Risk Reduction Target (RRT) value and Control Effectiveness Profile (CEP) score from [[Main I&C/Digital_Systems_Engineering_Framework#Hazards and Consequences Analysis for Digital Systems (HAZCADS) | EPRI Hazard Analysis Methods for Digital Instrumentation and Control Systems]] or
EMCAM enables a user to decide which technical or administrative control methods to apply during system design and assessment to achieve a risk reduction target (RRT) value and Control Effectiveness Profile (CEP) score provided from a corresponding hazards analysis process, such as Hazards and Consequences Analysis for Digital (HAZCADS). EMCAM uses the CEP score value and equipment location information to identify recommended EMC testing parameters (acceptance criteria, scope and limits) and additional controls for nuclear facility I&C equipment modifications.
* a user-defined qualitative risk tolerance that corresponds with the specific application or use of digital I&C equipment in a nuclear power facility.  
 
Recommendations are made regarding the selection of electromagnetic susceptibility and emissions testing scope and level requirements to demonstrate reasonable confidence of EMC commensurate with risk, and provides flexibility to tailor the testing scope, testing level and further control method allocation based on a particular set of application requirements.  


==Technical bases for testing limits==
This process enables a user to decide which technical or administrative control methods to apply during system design and assessment to achieve a risk reduction target (RRT) value and Control Effectiveness Profile (CEP) score provided from a corresponding hazards analysis process, such as HAZCADS. EMCAM uses the CEP score value and equipment location information to identify recommended EMC testing parameters (acceptance criteria, scope and limits) and additional controls for nuclear facility I&C equipment modifications.
Testing limits in the TR-102323 "recommended practices" and EMCAM were originally developed from data collected by EPRI in 1993-1994 and are documented them.
 
The limits have been questioned serval times as overly conservative mainly due to data misinterpretation. Two reports have been issued to review the bases for the data in particular for the conducted emissions susceptibility (CS) test, CS114.
===EMCAM versions access table===
* [https://www.epri.com/research/products/000000000001007998 Review of High Frequency Conducted Susceptibility Limits: Assessment of CS114 Test Limits in TR-102323]:  published in 2003, it documents a review of the bases for the high-frequency conducted emission susceptibility (CS) test limits recommended in EPRI Report TR-102323 (Revisions 0-2) for testing and qualifying equipment to be installed in nuclear power plants. The primary purpose of the investigation was to provide additional information to support EMI Working Group discussions of the problems that are consistently experienced with this part of EMI qualification testing. The report provides recommendations on potential ways to develop additional bases for revising the current recommended limits for this testing.
{| class="wikitable" style="margin:left"
* [https://www.epri.com/research/products/000000000001016158 Review of High Frequency Conducted Susceptibility Limits for Electromagnetic Compatibility Testing]: published in 2007, it documents the technical basis for the CS114 test levels in Regulatory Guide 1.180, Revision 1, and provides technical justification for changes to the existing industry and NRC guidance on CS114 qualification tests.
|+
|-
! Revision # !! Publication year !! Revision notes 
|-
| [https://www.epri.com/research/products/000000003002023743 '''Revision 0'''] ||  style="text-align:center;" | 2023 || The first issue of EPRI's risk-informed EMC assessment.  
|-
|}


= Technology Assessments and Troubleshooting Methods and Results Reports=
= Technology Assessments and Troubleshooting Methods and Results Reports=
Another areas of work for EPRI were:
EPRI also developed the following EMC guidance to help guide technology implementation and use:
* the development of a troubleshooting guide to trace and correct EMI malfunctions, and
* A troubleshooting guide to help identify and correct EMI related malfunctions, and
* the assessment of new technologies that once introduced in the plants could cause EMI.
* An analysis of radiated emission levels from several intentional radio frequency emitters to help with determining appropriate controls supporting their usage inside a plant .


==Troubleshooting EMI==
==Troubleshooting EMI==
Line 87: Line 131:
|+  
|+  
|-
|-
! Title !! Publication date !! Description  
! Title !! Publication year !! Description  
|-
| Wireless Technology Assessment: Analysis of Radiated Emissions from Common Phones, Laptops, and Tablets - 2024 Update || style="text-align:center;" | 2024 || This report provides an update to the guidance contained in the previous report to include a sampling of the latest cellular phones, tablet devices, and other devices using these additional wireless communications protocols. The information contained in it is intended to provide the nuclear industry with example data from wireless technology to support their own internal evaluations of the technology and the establishment of associated exclusion zones.
|-
|-
| [https://www.epri.com/research/products/000000003002012707 Wireless Technology Assessment: Analysis of Radiated Emissions from Common Phones, Laptops, and Tablets ] || 2018 || Provides the bounding exclusion zones for three wireless protocols (Wi-Fi, Bluetooth, and LTE) and examines field strengths generated within the far-field of wireless transmission for a subset of wireless devices during normal operation.
| [https://www.epri.com/research/products/000000003002025348 Li-Fi Wireless Communications: Technology Evaluation for Utility Applications] || style="text-align:center;" | 2023 || This report includes discussions not only about radiated and electromagnetic emissions, but also examines the potential benefits and challenges of Li-Fi technologies related to security, spectrum output, and communication performance.  
|-
|-
| [https://www.epri.com/research/products/000000003002023839 EPRI Robotics Research: Electromagnetic Compatibility Assessment of SPOT Robotic Platform] || 2022 || Documents the completed electromagnetic compatibility testing of a Spot robot for radio frequency emissions, and susceptibility characterization in accordance with EPRI product 3002015757, Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment, Revision 5 to TR-102323.  
| [https://www.epri.com/research/products/000000003002023839 EPRI Robotics Research: Electromagnetic Compatibility Assessment of SPOT Robotic Platform] || style="text-align:center;" | 2022 || Documents the completed electromagnetic compatibility testing of a Spot robot for radio frequency emissions, and susceptibility characterization in accordance with EPRI product 3002015757, Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment, Revision 5 to TR-102323.  
|-
|-
| [https://www.epri.com/research/products/000000003002025348 Li-Fi Wireless Communications: Technology Evaluation for Utility Applications] || 2023 || This report includes discussions not only about radiated and electromagnetic emissions, but also examines the potential benefits and challenges of Li-Fi technologies related to security, spectrum output, and communication performance.  
| [https://www.epri.com/research/products/000000003002012707 Wireless Technology Assessment: Analysis of Radiated Emissions from Common Phones, Laptops, and Tablets ] || style="text-align:center;" | 2018 || Provides the bounding exclusion zones for three wireless protocols (Wi-Fi, Bluetooth, and LTE) and examines field strengths generated within the far-field of wireless transmission for a subset of wireless devices during normal operation.
|-
|-
| Wireless Technology Assessment: Analysis of Radiated Emissions from Common Phones, Laptops, and Tablets - 2024 Update || Pending || This report provides an update to the guidance contained in the previous report to include a sampling of the latest cellular phones, tablet devices, and other devices using these additional wireless communications protocols. The information contained in it is intended to provide the nuclear industry with example data from wireless technology to support their own internal evaluations of the technology and the establishment of associated exclusion zones.
| [https://www.epri.com/research/products/000000003002011818 Wireless Sensor Survey and General Specification] || style="text-align:center;" | 2018 || This report presents the various wireless sensor technologies that are commercially available; an overview of EMI/RFI concerns for wireless sensor technology, including laboratory test results for numerous sensors; guidance for specifying and procuring wireless sensor technology to meet a particular equipment condition monitoring application; and the suggested responsibilities of various departments within the power plant during the implementation of wireless technology.  
 
 
 
|-
|-
|}
|}


=EMI Documented Experiences Analysis=
=EMI Documented Experiences Analysis=
EPRI has documented the analysis of EMI events to inform the industry of EMI risks and offer suggestion on how they can be further mitigated.
EPRI has documented the analysis of EMI events to inform the industry of EMI risks and offer suggestion on how they can be further mitigated (see the table below). Additionally, [https://www.epri.com/research/products/000000003002015757 Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment: Revision 5 to TR-102323] in its appendix L includes a summary of lessons learned and OE obtained from the 2011 report mentioned in the table and EMI events are presented in EPRI EMI Qualification of Digital Equipment Upgrades CBT mentioned in the Training Materials section above.
 
{| class="wikitable" style="margin:left"
{| class="wikitable" style="margin:left"
|+  
|+  
Line 106: Line 156:
! Title !! Publication year !! Description  
! Title !! Publication year !! Description  
|-
|-
| [https://www.epri.com/research/products/000000000001018702 Indian Point-2 Flash Photography Event ] || 2009 || This report presents the results of an independent assessment by the EPRI Electromagnetic & Radio Frequency Interference Working Group on a flash photography event at the Indian Point-2 (IP-2) nuclear power plant.
| [https://www.epri.com/research/products/000000000001022984 Assessment of Electromagnetic Interference Events in Nuclear Power Plants ] || style="text-align:center;" | 2011 || This report seeks to identify, collect, and analyze the EMI-related incidents in an effort to understand the level and trends in these events. Beyond trends, the analysis probes the causal factors of the events. The fundamental physics of the events is studied with the objective of using an improved understanding of the physics of interference for evaluating the range of mitigations that are possible.
|-
| [https://www.epri.com/research/products/000000000001018702 Indian Point-2 Flash Photography Event ] || style="text-align:center;" | 2009 || This report presents the results of an independent assessment by the EPRI Electromagnetic & Radio Frequency Interference Working Group on a flash photography event at the Indian Point-2 (IP-2) nuclear power plant.
* To confirm or clarify the root cause of the IP-2 BFP runback.
* To confirm or clarify the root cause of the IP-2 BFP runback.
* To recommend measures to correct susceptibility of IP-2 BFP controls to electromagnetic interference (EMI)/RFI.
* To recommend measures to correct susceptibility of IP-2 BFP controls to electromagnetic interference (EMI)/RFI.
* To reevaluate best practices for digital camera use in accordance with EPRI report TR-102323 Rev. 3.
* To reevaluate best practices for digital camera use in accordance with EPRI report TR-102323 Rev. 3.
|-
|-
| [https://www.epri.com/research/products/000000000001022984 Assessment of Electromagnetic Interference Events in Nuclear Power Plants ] || 2011 || This report seeks to identify, collect, and analyze the EMI-related incidents in an effort to understand the level and trends in these events. Beyond trends, the analysis probes the causal factors of the events. The fundamental physics of the events is studied with the objective of using an improved understanding of the physics of interference for evaluating the range of mitigations that are possible.
|}
 
=Record of Revisions=
{| class="wikitable" style="margin:left"
|+
|-
! Number !! Date !! Description of changes
|-
|-
| 0 || August 2024 || Initial release
|}
|}
Additionally, [https://www.epri.com/research/products/000000003002015757 Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment: Revision 5 to TR-102323] in its appendix L includes a summary of lessons learned and OE obtained from the 2011 report mentioned in the table above and EMC events presented in EPRI [https://www.epri.com/research/products/000000003002018372 EMI Qualification of Digital Equipment Upgrades in Nuclear Power Plants - Computer-Based Training].

Latest revision as of 18:46, 2 August 2024

EPRI EMI & EMC research topical areas

Revision 0

Electromagnetic signals can produce malfunctions at the component, equipment, subsystem and system level if not properly controlled and compatible with their environment. These disturbances created by either natural (lightning, Electrostatic Discharge (ESD), etc.) or man-made sources (radio transmissions) present I&C design, maintenance, and reliability challenges when electromagnetic interference (EMI) affects either safety or non-safety and important to power production functions. These malfunctions can result in time consuming delays, forced outages, or other severe consequences. Hence, electromagnetic Compatibility (EMC) and the practices that promote compatibility play an important role in managing the I&C equipment lifecycle and promoting equipment reliability.

The following Wiki provides an outline of existing EPRI EMC guidance related to the following topics:

Background[edit]

System and component EMC refers to the equipment’s ability to function, as designed, without adverse degradation or failure due to interference sources operating in its intended environment. EMC also refers to the equipment’s ability to function without adversely affecting other equipment connected to or located in that environment.

Emissions, whether deliberate or unintended, are electromagnetic energy generated by one or more radiating or conducting sources. This energy is released into the ambient environment which can create EMI. EMI can degrade or cause failures of equipment in the surrounding area or within a device or its enclosure.

EMC assessment is a process that involves:

  • Understanding anticipated continuous-wave and transient emissions in the environment where equipment will be installed
  • Selecting a device or system that is intended to be compatible with the environment
  • Evaluating the immunity of the device or system to ensure it will perform reliably as designed when exposed to expected electromagnetic emissions
  • Evaluating the emissions of the device or system to ensure it does not exceed acceptable thresholds thus creating the potential to cause interference with existing equipment local to the point of installation
  • Installing and maintaining the system as intended for an acceptable level of EMC

Reasonable assurance of EMC can be achieved by satisfying each of the bullets above.

EPRI Guidance and Training on EMC Fundamentals[edit]

EMC Handbook[edit]

EPRI's Handbook for Electromagnetic Compatibility of Digital Equipment in Power Plants is a dual volume publication that is available to the public. The handbook explains the fundamentals of electromagnetic compatibility and provides guidelines for ensuring the electromagnetic compatibility of digital equipment in power plants. The handbook is applicable to digital equipment being installed in all types of power plants.

  • Volume 1 - Fundamentals of EMI Control: presents a comprehensive and theoretical discussion of the fundamentals of EMI control. This volume is a reference to assist the reader in answering questions encountered and to fully understand potential and existing EMI problems.
  • Volume 2 - Implementation Guide for EMI Control: presents a practical implementation guide for EMI control, beginning with design and procurement through testing and installation; it also includes information on operation and maintenance.

Training Materials[edit]

EPRI provides training on EMI & EMC fundamentals and its guidance documents addressing the subject, browse EPRI Training and Development Platform for future guided training opportunities.

For self-paced learning opportunities on the topic, review:

An instructor-led EMC fundamentals training is in development and will be available from EPRI in the future.

EPRI's Guidance on EMC Testing and Control Method Allocation[edit]

EPRI’s EMI testing and control method allocation guidance resides in two flagship products that are further described (motivations and evolution) in the following sections:

  • Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment (TR-102323), and
  • Electromagnetic Compatibility Assessment Methodology (EMCAM)

Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment (TR-102323)[edit]

The initial version of EPRI Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment, referred to as TR-102323, was focused on stabilizing the licensing process associated with U.S. nuclear plant digital I&C equipment upgrades. The initial publication addressed the following fundamental concepts:

  • Recommended electromagnetic and radio interference (EMI/RFI) susceptibility testing levels
  • Recommended equipment emissions testing levels
  • Recommended design and installation practices

Future revisions to TR-102323 up to and including the current revision 5 build on those fundamental concepts. See TR-102323 table below for a list of versions of this guidance with descriptions of the main changes between them and links for access in EPRI website.

The TR-102323 methodology and recommended testing limits accomplish the following two objectives:

  1. Ensure equipment susceptibility limits bound measured plant emissions levels by a margin of at least 8 dB or more (see Bounding Plant Emissions figure below). The 8 dB susceptibility margin was required to obtain U.S. Nuclear Regulatory Commission (NRC) endorsement for “Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment” Revision 1 to EPRI TR-102323.
  2. Establish one set of bounding equipment susceptibility and emissions testing limits to qualify equipment one-time for use in any commercial power plant in any location.
Bounding Plant Emissions (Source: TR-102323 Appendix N)


In addition to recommending susceptibility limits that support one-time qualification testing that bounds plant emissions, TR-102323 also provides a graded approach for testing systems based on safety classification and the potential impact to plant operations. Table 5-1 Testing Applicability on TR-102323, documents a complete suite of susceptibility type tests applicable for safety related applications, recommends the same suite of susceptibility type tests for applications that are non-safety related and important to power production, and provides optional susceptibility testing guidance for other non-safety related applications. Table 5-1 also documents applicable high-frequency conducted and radiated equipment emissions testing for each of the aforementioned applications. This provides assurance that new equipment installed in a facility, regardless of its safety classification, will not interfere with safety-related equipment.

The TR-102323 methodology provides high assurance of EMC and attempts to reduce the need for subsequent re-qualification based on a modified use case. While this can eliminate the need to repeat susceptibility or emissions testing to different testing levels for each application, qualification to lower susceptibility or higher emissions limits may be technically acceptable and also reduce qualification costs in certain applications.


TR-102323 versions access table[edit]

Revision # Publication year Revision notes
Revision 5 2024 (Errata)

2019

The latest revision, incorporates all learnings from past versions and contains in the appendixes the technical bases for the changes. It also adds additional guidance and clarification to various sections of the document based on current events and issues experienced by the nuclear power industry. This includes the addition of an example exclusion zone calculation with clarification supporting each equation recommended for use by the guideline, arc welding EMI suppression guidance, adjustable and variable frequency speed drives EMI suppression guidance, lighting system EMI suppression guidance, wireless emissions control guidance, a summary of lessons learned and operating experience from nuclear industry related EMI events.

The Errata version corrects an issue in the heading row for Table K-1, the column labels for Low-Frequency and High-Frequency under Emission Test for Radiated were transposed.

Revision 4 2020 (Errata)

2013

This revision of the EPRI guidance made better use than previous ones of EMC testing standards commonly used by equipment vendors and suppliers and generally reduced differences with the recommendations of NRC Regulatory Guide 1.180, Revision 1. Where differences remained, the bases for the Revision 4 position were provided. One issue of special note in Revision 4 is its treatment of CS114. The CS114 test levels recommended in previous revisions of this report and in Regulatory Guide 1.180, Revision 1, were based on plant data acquired by EPRI in the early 1990s. The latest results indicate that the early data was misapplied, and less conservative test levels were recommended.

The Errata version corrects a discrepancy on the RS103 test frequency range appearing in Chapter 5 and on MIL-STD-461G and the one appearing in Appendix K.

Revision 3 2004 Not available on EPRI website, revision 3 incorporated the results of the 2003 reevaluation of the conducted susceptibility limits and proposed less conservative test levels.
Revision 2 2000 This version revised the limits to reduce excessive conservatism, based on plant operating experience since the first version of the guide was released and broader frequency ranges to accommodate newer telecommunication devices.
Revision 1 1997 Conditional on incorporation of a number of clarifications and publication of a revised report, the NRC issued a Safety Evaluation Report in April 1996 endorsing the revised report (the future revision 1). Since revision 1 was published, the TR-102323 became a de facto standard within the U.S. nuclear industry.

NOTE: The SER report has been maintained in the appendixes of the subsequent revisions of this guidance.

Revision 0 1994 Not available on EPRI website, this first issue and was submitted to the NRC for revision.

Electromagnetic Compatibility Assessment Methodology (EMCAM)[edit]

While TR-102323 supports a graded approach based on safety classification, it does not consider risk associated with different system use cases and applications. This is the intent of the Electromagnetic Compatibility Assessment Methodology (EMCAM). It provides risk-informed guidance for equipment EMC qualification and control method allocation. EMCAM is an alternate approach for assessing electromagnetic compatibility for a facility change and is not intended to replace the TR-102323 methodology. The two methods are compatible, and EMCAM does not invalidate any legacy equipment EMC qualification testing results. EMCAM is intended to complement the EPRI Digital Engineering Guide (DEG) in the conceptual or detailed design phase of an I&C project. The methodology evaluates EMC testing performance and control method allocation in new or modified I&C equipment designs using facility risk (e.g., impact to CDF) and application (e.g., installation environment classification) insights. Using the process requires either:

Recommendations are made regarding the selection of electromagnetic susceptibility and emissions testing scope and level requirements to demonstrate reasonable confidence of EMC commensurate with risk, and provides flexibility to tailor the testing scope, testing level and further control method allocation based on a particular set of application requirements.

This process enables a user to decide which technical or administrative control methods to apply during system design and assessment to achieve a risk reduction target (RRT) value and Control Effectiveness Profile (CEP) score provided from a corresponding hazards analysis process, such as HAZCADS. EMCAM uses the CEP score value and equipment location information to identify recommended EMC testing parameters (acceptance criteria, scope and limits) and additional controls for nuclear facility I&C equipment modifications.

EMCAM versions access table[edit]

Revision # Publication year Revision notes
Revision 0 2023 The first issue of EPRI's risk-informed EMC assessment.

Technology Assessments and Troubleshooting Methods and Results Reports[edit]

EPRI also developed the following EMC guidance to help guide technology implementation and use:

  • A troubleshooting guide to help identify and correct EMI related malfunctions, and
  • An analysis of radiated emission levels from several intentional radio frequency emitters to help with determining appropriate controls supporting their usage inside a plant .

Troubleshooting EMI[edit]

The Electromagnetic Interference (EMI) Troubleshooting Guide assists practitioners with the development of a troubleshooting methodology that can be used by utility personnel to diagnose and resolve EMI issues. The report provides the necessary background and supporting information to develop an EMI troubleshooting guide that will help save time and money by making it easier to trace, diagnose and resolve EMI issues in the field. It may be used by utilities to directly implement its guidance at a facility or to aid in interactions with vendors by ensuring a common understanding and compliance with reputable electromagnetic compatibility standards and techniques.

Technology Assessment Reports[edit]

EPRI continues to assess new technologies introduced at the plants to identify EMI issues and propose control methods to ensure EMC compatibility. Available assessments are listed in the table below:

Title Publication year Description
Wireless Technology Assessment: Analysis of Radiated Emissions from Common Phones, Laptops, and Tablets - 2024 Update 2024 This report provides an update to the guidance contained in the previous report to include a sampling of the latest cellular phones, tablet devices, and other devices using these additional wireless communications protocols. The information contained in it is intended to provide the nuclear industry with example data from wireless technology to support their own internal evaluations of the technology and the establishment of associated exclusion zones.
Li-Fi Wireless Communications: Technology Evaluation for Utility Applications 2023 This report includes discussions not only about radiated and electromagnetic emissions, but also examines the potential benefits and challenges of Li-Fi technologies related to security, spectrum output, and communication performance.
EPRI Robotics Research: Electromagnetic Compatibility Assessment of SPOT Robotic Platform 2022 Documents the completed electromagnetic compatibility testing of a Spot robot for radio frequency emissions, and susceptibility characterization in accordance with EPRI product 3002015757, Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment, Revision 5 to TR-102323.
Wireless Technology Assessment: Analysis of Radiated Emissions from Common Phones, Laptops, and Tablets 2018 Provides the bounding exclusion zones for three wireless protocols (Wi-Fi, Bluetooth, and LTE) and examines field strengths generated within the far-field of wireless transmission for a subset of wireless devices during normal operation.
Wireless Sensor Survey and General Specification 2018 This report presents the various wireless sensor technologies that are commercially available; an overview of EMI/RFI concerns for wireless sensor technology, including laboratory test results for numerous sensors; guidance for specifying and procuring wireless sensor technology to meet a particular equipment condition monitoring application; and the suggested responsibilities of various departments within the power plant during the implementation of wireless technology.


EMI Documented Experiences Analysis[edit]

EPRI has documented the analysis of EMI events to inform the industry of EMI risks and offer suggestion on how they can be further mitigated (see the table below). Additionally, Guidelines for Electromagnetic Compatibility Testing of Power Plant Equipment: Revision 5 to TR-102323 in its appendix L includes a summary of lessons learned and OE obtained from the 2011 report mentioned in the table and EMI events are presented in EPRI EMI Qualification of Digital Equipment Upgrades CBT mentioned in the Training Materials section above.

Title Publication year Description
Assessment of Electromagnetic Interference Events in Nuclear Power Plants 2011 This report seeks to identify, collect, and analyze the EMI-related incidents in an effort to understand the level and trends in these events. Beyond trends, the analysis probes the causal factors of the events. The fundamental physics of the events is studied with the objective of using an improved understanding of the physics of interference for evaluating the range of mitigations that are possible.
Indian Point-2 Flash Photography Event 2009 This report presents the results of an independent assessment by the EPRI Electromagnetic & Radio Frequency Interference Working Group on a flash photography event at the Indian Point-2 (IP-2) nuclear power plant.
  • To confirm or clarify the root cause of the IP-2 BFP runback.
  • To recommend measures to correct susceptibility of IP-2 BFP controls to electromagnetic interference (EMI)/RFI.
  • To reevaluate best practices for digital camera use in accordance with EPRI report TR-102323 Rev. 3.

Record of Revisions[edit]

Number Date Description of changes
0 August 2024 Initial release