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    Master Functional Safety: Sis Design And Sil Calculations

    Posted By: ELK1nG
    Master Functional Safety: Sis Design And Sil Calculations

    Master Functional Safety: Sis Design And Sil Calculations
    Published 7/2025
    MP4 | Video: h264, 1920x1080 | Audio: AAC, 44.1 KHz
    Language: English | Size: 5.83 GB | Duration: 6h 30m

    Become an expert in Functional Safety SIL Assessment and SIS design -Prepare CFSE certification with real-world examples

    What you'll learn

    Master IEC 61508 and IEC 61511 standards - Understand fundamental principles, safety lifecycle implementation, and compliance requirements for SIS

    Master SIS system architectures and configurations

    Understand 1oo1, 1oo2, 2oo2, and 2oo3 configurations and select the optimal architecture for specific safety requirements and SIL targets

    Perform accurate SIL calculations and assessments - Calculate SIL levels using quantitative methods, PFDavg calculations, and system architecture

    Design robust Safety Instrumented System - Apply system architectures, understand common cause factors, hardware fault tolerance, and safe failure fractions

    Implement comprehensive protection strategies - Master the 10-layer protection model from BPCS to emergency response including prevention and mitigation layers

    Apply valve testing strategies in SIS - Understand Partial Stroke Testing (PST) and Full Stroke Testing (FST) effects on system performance and SIL achievement

    Prepare for CFSE certification - Gain the advanced knowledge and practical skills for the prestigious Certified Functional Safety Engineer certification

    Requirements

    Basic engineering background - Undergraduate degree in engineering (chemical, electrical, mechanical, or related field) or equivalent industrial experience

    Fundamental process knowledge - Understanding of industrial processes, control systems, and instrumentation concepts

    No specialized software required - All calculations demonstrated using standard methods and principles applicable to any SIL calculation tool

    Recommended but not required - Basic familiarity with reliability engineering concepts (MTTR, MTTF, failure rates) will enhance learning experience

    Commitment to learning - Willingness to complete quizzes and practice calculations to master the material thoroughly

    Description

    Master the critical skills of functional safety engineering with this comprehensive course designed by a Certified Functional Safety Engineer (CFSE) and Certified Process Safety Professional (CCPSC) with extensive hands-on experience in hazard identification, risk analysis, and SIL determination according to IEC 61508 and IEC 61511 standards.This industry-leading course provides over 6 hours of expert instruction across 7 specialized modules, covering everything from fundamental safety concepts to advanced SIL calculations. You'll gain practical expertise in Safety Instrumented Systems (SIS) design, system architectures, and real-world application through multiple calculation examples including hydrogen compressor, air measurement, oxygen measurement, level measurement, and temperature monitoring systems.Starting with essential foundation concepts, you'll explore the complete 10-layer protection strategy for hazardous events, from basic process control systems to emergency response plans. The course thoroughly covers reliability engineering principles, including MTTF, MTTR, failure rates, and common cause failures that are crucial for accurate SIL assessments.Deep-dive into Safety Instrumented Systems architecture with detailed coverage of 1oo1, 1oo2, 2oo2, and 2oo3 configurations, understanding how each impacts system performance and SIL achievement. Learn advanced concepts including Hardware Fault Tolerance (HFT), Safe Failure Fraction (SFF), and PFDavg calculations that form the backbone of functional safety engineering.The course includes specialized training on valve testing strategies, covering Partial Stroke Testing (PST) and Full Stroke Testing (FST) and their effects on system reliability. Master the IEC 61508 fundamental concepts including safety lifecycle implementation, quantitative SIL determination methods, and compliance requirements.Each section includes comprehensive knowledge-testing quizzes (165 questions total) to reinforce learning and ensure mastery of critical concepts. The course culminates with hands-on SIL calculation practice sessions that mirror real industrial scenarios, preparing you for professional certification and immediate workplace application.Whether you're pursuing CFSE certification or advancing your career in process safety, this course provides the authoritative training needed to excel in functional safety engineering roles across oil & gas, chemical processing, pharmaceutical, and other high-risk industries.Master the Standards. Achieve Certification. Protect LivesWR Training - Your trusted learning providerSpread the wings of your knowledge

    Overview

    Section 1: Presentation of IEC 61508 and IEC 61511

    Lecture 1 Introduction

    Lecture 2 Scope of IEC 61508

    Lecture 3 Safety

    Lecture 4 IEC 61508 - Brief description

    Lecture 5 Other safety related standards

    Lecture 6 Before to proceed to the next section

    Section 2: Prevention and mitigation layers for hazardous events

    Lecture 7 Introduction

    Lecture 8 Prevention Layer #1 - Plant and processes

    Lecture 9 Prevention Layer #2 - Basic Process Control Systems (BPCS)

    Lecture 10 Prevention Layer #3 - Alarm systems

    Lecture 11 Prevention Layer #4 - Safety Instrumented Systems (SIS)

    Lecture 12 Prevention Layer #5 - Physical protection

    Lecture 13 Mitigation Layer #6 - Physical containment

    Lecture 14 Mitigation Layer #7 - Scrubbers and flares

    Lecture 15 Mitigation Layer #8 - Fire and gas systems

    Lecture 16 Mitigation Layer #9 - Internal emergency plan

    Lecture 17 Mitigation Layer #10 - External emergency plan

    Lecture 18 Considerations on protection levels

    Lecture 19 Before to proceed to the next section

    Section 3: Basic concepts of safety standards

    Lecture 20 Introduction

    Lecture 21 Reliability

    Lecture 22 Unreliability

    Lecture 23 Availability and unavailability

    Lecture 24 More about "availability"

    Lecture 25 Achievable availability

    Lecture 26 Operational availability

    Lecture 27 MTTF, MTTR, MTBF and their relations

    Lecture 28 Failure rate

    Lecture 29 Components with constant failure rate

    Lecture 30 Failure rate categories

    Lecture 31 Common cause failures

    Lecture 32 Safety analysis with SIL selection

    Lecture 33 Before to proceed to the next section

    Section 4: Safety Instrumented Systems (SIS)

    Lecture 34 Introduction to SIS

    Lecture 35 Safety requirements

    Lecture 36 Safety Integrity Levels (SIL)

    Lecture 37 System architectures

    Lecture 38 System architectures - 1oo1

    Lecture 39 System architectures - 1oo2

    Lecture 40 System architectures - 2oo2

    Lecture 41 System architectures - 2oo3 and 1oo2D

    Lecture 42 Common cause factor (β) and PFDavg for redundant architectures

    Lecture 43 More on 1oo1 system architectures

    Lecture 44 Effect of manual periodic tests on PFDavg calculation for 1oo1 architectures

    Lecture 45 Effect of manual test duration on PFDavg calculation for 1oo1 architectures

    Lecture 46 PFDavg interpretation

    Lecture 47 More on 1oo2 system architectures

    Lecture 48 1oo2 architecture for final element only

    Lecture 49 More on 2oo3 system architectures

    Lecture 50 Comparison between system architectures

    Lecture 51 Practical example #1

    Lecture 52 Practical example #2

    Lecture 53 Practical example #3

    Lecture 54 Before to proceed to the next section

    Section 5: Use of valves in Safety Instrumented Systems

    Lecture 55 Bypass examples

    Lecture 56 Partial Stroke Test (PST) for valves

    Lecture 57 More on Partial Stroke Tests (PST)

    Lecture 58 Full Stroke Test (FST) for valves

    Lecture 59 Effects of PST and FST on PFDavg and SIL

    Lecture 60 Before to proceed to the next section

    Section 6: SIS conceptual design

    Lecture 61 Design requirements

    Lecture 62 Before to proceed to the next section

    Section 7: IEC 61508 - Fundamental concepts

    Lecture 63 Safety lifecycle

    Lecture 64 Safety Integrity Levels (SIL)

    Lecture 65 Hardware Fault Tolerance (HFT)

    Lecture 66 More on HFT

    Lecture 67 Safe Failure Fraction (SFF)

    Lecture 68 Quantitative method for SIL determination

    Lecture 69 Before to proceed to the next section

    Section 8: Practice session - SIL calculations

    Lecture 70 Quick review of the SIL calculation method

    Lecture 71 Example #1 - Hydrogen compressor

    Lecture 72 Example #2 - Air measurement

    Lecture 73 Example #3 - Oxygen measurement

    Lecture 74 Example #4 - Level measurement

    Lecture 75 Example #5 - Temperature monitoring

    Section 9: Downloadable resources

    Lecture 76 Watch me

    Process Safety Engineers seeking comprehensive SIS and functional safety expertise for career advancement and CFSE certification preparation,Instrumentation and Control Engineers working with safety systems who need to understand SIL requirements and system design principles,Project Engineers and Managers overseeing safety-critical projects in oil & gas, chemical, pharmaceutical, and manufacturing industries,Safety Professionals expanding their expertise into functional safety and Safety Instrumented Systems design and assessment,Engineering Consultants requiring authoritative knowledge of IEC 61508/61511 standards for client projects and regulatory compliance,Experienced Engineers preparing for the Certified Functional Safety Engineer (CFSE) examination and seeking structured, comprehensive training,Technical Professionals in high-risk industries who need to understand, specify, or verify Safety Instrumented Systems performance