Safety Instrumented System (SIS) Principles Comprehensive & Understanding Training

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DEVELOP Training Center menyelenggarakan TrainingSafety Instrumented System (SIS) Principles ComprehensiveUnderstanding yang sangat berguna untuk mendapatkan skill tentangSafety Instrumented System (SIS) Design, Analisis dan Report pada ProjectPlant Operation.

Materi Training di DEVELOP Training Center dirancang khusus oleh para praktisi engineer dan designer disesuaikan dengan kebutuhan project. Anda akan mendapat sharing ilmu langsung dari para praktisi yang berpengalaman bertahun-tahun.

DEVELOP menerapkan Syllabus Training Safety Instrumented System (SIS) Principles Comprehensive Understanding dengan tahap-tahap pembelajaran berkualitas sbb :

Sesi 1-2 Safety Life Cycle,Functional Safety,Safety Instrument System,Hazard Identification, SIL determination IEC 61511-3,LOPA Safety Requirement Specification/SRS
Skill Focus :
Safety life cycle (Design,Constructionas built Changes after Commissioning)
Accident Causes in Industry
Failure Prevention
Functional SafetySafety Instrument System/SIS Standard-Code : IEC 61511 IEC 61508-4
Safety Instrument System/SIS to build safer system,more cost effective systemframework for consistent Functional Safety design
Process Safety,BPCSProtection Layers
Functional Safety Assessment/Audit,Safety Lifecycle StructurePlanning
HazardRisk Assessment,Allocation of Safety Functions to protection layers
Safety Requirement to Safety Instrument System/SIS
DesignEngineering of Safety Instrument System/SIS
DesignDevelopment for Risk Reduction
InstallationCommissioning Validation
Operation-Maintenance,ModificationDecommissioning
Safety Instrument System/SIS Verification
Safety Instrument Function/SIF (Sensors,Logic Solver,Final Elements)
Safety Integrity Level/SIL Levels 1-2-34 (Demand Mode of Operation,Failure Probability,Target Risk Reduction)
CCPS Hazard CCPS (harm to people,property,or environment)
Hazard identification
Hazard Deviation,Causes,Consequences,SafeguardsRecommendation
Process Risk Criteria
Quantitative Hazard Identification Method
Identify Potential Hazard-operational problemsconsequences, with StructuredSystematic Examination
Management Commitment,Knowledge Experience,Information PID-PFD-SOP
Multidiscipline HAZOP Team Review (Design Purpose,Deviation,ConsequencesAction Safeguards)
HAZOP Case Study
SIL determination comply with IEC 61511-3
Residual Risk,Tolerable RiskProcess Risk
Mitigation (Plant Emergency Response Layers,Passive Protection Layers,Relief Valve-Rupture Disk Active Protection Layers)
Prevention (Emergency Shutdown Safety Layers,Process Shutdown,Process AlarmProcess Value/Basic Process Control System)
LOPA for SIL determination
LOPA OverviewHow LOPA Works (Scenarios,event frequency,IPL,risk decision,consequence and severity)
LOPA Scenario Initiating Event,Enabling eventconsequences (over-pressuring the system, release of toxic or flammable, fatality etc)
LOPA Conditional Modifier (Probability of ignition,person present,fatal injuryfinancial loss)
Information Net Used in LOPA (Independent Protection Layers/IPLs,Probability of Failure on Demand/PFD,SeverityFrequency,Risk ToleranceSafe Result/Outcome)
IPL Rules (Effective,IndependentAuditable)
LOPA Case Study
Control Loop Failure,Seal Failure,Gasket Failure,Rotating Equipment Trip,Fixed Equipment Failure,Loss of Power,Utility Failure
Process Safety Valve,Flame Arrestor,Independent Control Loop,CRO with alarm
Human Errors
Probability of failure on demand average (PFDavg)
Hazard and Risk Assessment
Determining RRF to have SIL
Failure Rate for Process Components (Controller,Control Valve,Flow Measurement Fluids-Solids,Flow Switch,Gas-Liquid Chomarograph,Level Measurement Fluids-Solids,Oxygen Analyzer,Solenoid Valve etc)
Safety Requirement Specification (SRS)
Sesi 3-4 HFT vs Voting,SIS Design Engineering,Logic Solver,IO,EWS/OWS/SOE,Safety Shutdown System Architecture,Final ElementsSIL Verification
Skill Focus :
HFT Vs Voting (Architecture,Voting,HFTRedundancy)
SIS Design Engineering
Safety Reliability Data (Safe Detected/Undetected, Dangerous Detected/Undetected Detail Errors)
Test Interval (PFD Test Period,Interval of Operation,Time Interval,Proof Test Interval in years,Voting,PFDavg,Architecture)
Sensor (Certified IEC61508,Reliability Data,Transmitter,SwitchDiagnostic NAMUR NE43)
Logic Solver (Certified IEC61508 latest,Safety Reliability,Controller,Communication,Power,I/OSIL capability)
Controller Design,Communication ModulePower Supply Module
Input Output
Redundant or simplex IO,Galvanic isolated/optically isolated/electrical isolated
Analog modules HART pass thruNAMUR 43
Digital modules AC-DC
Interposing relay SIL 2 certified
Input output with SIL-2SIL-3 Surge Protection
System Diagnostic
EWS, OWS, SOE, Operator Interface
programmingconfiguration in EWS
Partial Stroke Test
logic programmed using Function Block
SOE c/w event reporting facility
Controller response time
MaintenanceOperation Override by hard key switches/Soft programmed HMI Human Machine Interface
Safety Shutdown System Architecture (Ews-Ows-Soe,Safety Network,Fire Gas System/FGS Control Panel,Hardwire,ModbusDCS Control Panel)
Final Elements
IEC 61508 comply
Safety Reliability Data
Shutdown ValvesBlow Down Valves (Ball Valves)
Stroking Time
TSO
Diagnostictest device (Partial Stroke Test Device, Position Limit Switches etc)
SIL Verification
Results from LOPA and SRS
Final Verification and Recommendation for the Evaluated SIF
Case Study

Pembahasan materi mengetengahkan contoh-contoh latihan dalam konteks dunia proyek konstruksi sehingga lebih familier dengan aktivitas proyek sehari-hari.Selama training, instruktur kami akan menggunakan kombinasi teori serta praktek langsung dengan studi kasus yang telah dipersiapkan yang menyerupai Proyek nyata.

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