Our courses help engineers, technologists, and industrial safety specialists systematically approach risk analysis and minimization at all stages of asset lifecycle: design, construction, operation, modernization.

Training is based on ISO 31000, ISO 31010, API 580/581, GOST R 27.012-2019 standards. Formats: in-person, online, hybrid, corporate programs with adaptation. Certification - with registration in the FRDO registry.

📌 Official Courses

RA-101 | Technological Risk Analysis (PHA - Process Hazard Analysis)

Comprehensive approach to identification and assessment of technological risks at hazardous production facilities. Analysis methods applied at all stages of facility lifecycle. Implementation of systematic approach to risk management. Format: in-person/online | Days: 5 | Cost: 80,000 ₽ | Validity: 3 years

RA-102 | Hazard Identification and Risk Assessment (HAZID / ENVID)

Methods for early hazard identification during design and modernization phases. Conducting HAZID/ENVID sessions, risk ranking, probability and consequence assessment, cause/effect matrix. Format: in-person/online | Days: 2 | Cost: 50,000 ₽ | Validity: 3 years

RA-103 | Hazard and Operability Analysis (HAZOP)

Qualitative method for identifying deviations in technological processes. Working with guide words, conducting sessions, developing recommendations. Compliance with GOST R 27.012-2019. Format: in-person/online | Days: 3 | Cost: 70,000 ₽ | Validity: 3 years

RA-104 | Hazard and Operability Analysis HAZOP-SIL using Risk Graph Method

Combined approach: HAZOP + determination of Safety Integrity Levels (SIL). Using "Risk Graph" method to justify requirements for safety systems. Format: in-person/online | Days: 3 | Cost: 80,000 ₽ | Validity: 3 years

RA-105 | Hazard and Operability Analysis HAZOP and LOPA Method

Integration of HAZOP and LOPA for quantitative assessment of protective barrier adequacy. Determining IPL and SIL requirements. Practical assignments and group work. Format: in-person/online | Days: 3 | Cost: 80,000 ₽ | Validity: 3 years

RA-106 | Layer of Protection Analysis (LOPA)

LOPA method as a tool for evaluating the effectiveness of independent protection layers. Determining safety system requirements. Application in design and operation. Format: online | Days: 2 | Cost: 60,000 ₽ | Validity: 3 years

RA-107 | As Low As Reasonably Practicable (ALARP) Principle

Concept of "as low as reasonably practicable" risk level. Methodology for reducing risks to ALARP level. International and Russian approaches, practical examples. Format: online | Days: 1 | Cost: 50,000 ₽ | Validity: 3 years

💼 Seminars and Custom Programs (on request)

Law "On Technical Regulation" No. 184-FZ and risk assessment when working with it

Technical regulations.
National standards.
Product and service certification.
Accreditation of certification bodies and testing laboratories (centers).
State supervision (control).
Areas of activity not covered by the Law "On Technical Regulation". Mandatory requirements and risk assessment.
Finding reasonable balance between costs and acceptable risk level.

Law "On Industrial Safety of Hazardous Production Facilities" No. 116-FZ and risk assessment when working with it

Main elements of Federal Law 116 "On Industrial Safety of Hazardous Production Facilities".
Scope of the law.
Risk assessment.
Risk-based approach in state control (supervision) of enterprises.

Risk Management in accordance with ISO 31000 requirements

Risk concept and risk characteristics.
Definitions and general issues.
Risk management process.
Risk management goals and objectives.
Prevention and reduction, management.
Risk management system and structure.
Internal control in risk management system.

Main risk identification and analysis methods according to ISO 31010 standard

Analysis of ISO 31010 standard as supplement to ISO 31000, content and recommendations for selecting and applying risk assessment methods. Main provisions of ISO 31010 standard.
Fundamentals of risk management theory in quality management system.
Factor identification and analysis methods.
Implementation of risk management in quality management system. Examples of risk identification.

Alarm Management (Emergency Signal Management System for Process Control Systems)

Emergency signal management system is a continuous process, along with industrial safety, and is of paramount importance for ensuring safe operation of production and improving its productivity through:

Improving safety.
Improving operator and technological equipment efficiency.
Reducing unplanned downtime. Course objective — to provide understanding of emergency signal management system for process control systems, familiarize with best global practices, standards and approaches in this area. Discuss implemented alarm management solutions in Russian oil and gas companies and achieved effects.

Hazard source control and consequence management. Safety assurance methods

Process of hazard source control and consequence management. Hazard source identification.
Risk assessment matrix.
Hazard source and consequence registry.
Major accident hazard control.

Application of API 14C and API 17V in safety system design

American Petroleum Institute (API) 14C recommendations are guidelines for conducting safety system analysis, design, installation and testing on offshore oil and gas platforms. API 17V recommendations are applied for analysis, design, installation and testing of safety systems on subsea equipment of oil and gas platforms.

Brief overview of API standards.
API 14C overview — API 17V overview.
Practical examples of safety system analysis during design at hazardous production facilities.

Asset Integrity and Reliability

Asset integrity and reliability is the state of protection of hazardous production facilities from internal and external factors that may lead to accidents and incidents. Implementation of comprehensive measures to ensure equipment integrity and reliability allows not only to increase asset operation safety, but also to improve equipment efficiency/productivity.

definition of integrity and reliability and their role in ensuring safety and efficient equipment operation;
main elements of asset integrity management system to ensure required functions throughout asset lifecycle;
key tools for ensuring asset integrity;
regulatory framework for ensuring asset integrity and reliability;
global practices of asset integrity and reliability management systems.

Risk management organization in testing laboratories

Risk concept and risk characteristics for laboratories.
Risk management and crisis management terminology.
Risk management system and structure for testing laboratories.
Risk types and categories.
Risk identification tools, risk assessment and management methods: risk prevention or reduction, consequence management.