OSHAA 30-Hours Professional Diploma in Piping QA/QC Engineer

OSHAA 30-Hours Professional Diploma in Piping QA/QC Engineer

The OSHAA 30-Hours Professional Diploma in Piping QA/QC Engineer is a specialized training program designed to provide in-depth knowledge of quality assurance and quality control systems within piping engineering projects. Learners gain a structured understanding of how QA/QC processes ensure project safety, reliability, and adherence to approved technical standards. The curriculum blends theoretical principles with practical industrial insights to strengthen engineering competence.

This diploma emphasizes key areas including piping components, isometric drawing interpretation, welding inspection basics, non-destructive testing concepts, and quality documentation procedures. Participants learn how to review technical specifications, monitor fabrication and installation activities, and identify non-conformities within piping systems. The course highlights the importance of systematic inspection planning, reporting accuracy, and regulatory compliance. By understanding quality management frameworks and engineering workflows, learners develop the ability to support efficient project execution while maintaining high safety and quality standards.

The OSHAA 30-Hours Professional Diploma in Piping QA/QC Engineer also promotes analytical thinking, precision, and professional responsibility in industrial environments. It prepares individuals to coordinate effectively with engineering, construction, and inspection teams while maintaining proper documentation and quality records. The program reinforces structured quality control methodologies and industry best practices. Through focused training, participants enhance their technical expertise and build the confidence required to contribute effectively to piping QA/QC engineering operations.

Course Overview

Awarding Body

OSHAA

Duration

30-Hours 

Study Mood

Online

Assessment

Assignments Based

Course Study Units

  1. Introduction to Piping QA/QC Engineering (2 Hours)
  2. Piping Materials, Components, and Fabrication Methods (3 Hours)
  3. International Codes and Standards: ASME, API, ISO (4 Hours)
  4. Welding Processes and Procedure Qualification (4 Hours)
  5. Non-Destructive Testing (NDT) Techniques and Applications (4 Hours)
  6. Piping Isometrics and Technical Drawing Interpretation (3 Hours)
  7. Inspection and Test Plans (ITPs) in Piping Projects (5 Hours)
  8. Identification of Fabrication Defects and Site Quality Issues (2 Hours)
  9. QA/QC Documentation: WPS, PQR, NDT Reports, and Records (3 Hours)

Entry Requirements

  • Minimum age: Minimum age of 18 years.
  • Educational background: A basic educational background is recommended, preferably in engineering or technical disciplines.
  • Language proficiency: Proficiency in English language for reading, writing, and communication.
  • Work experience: Prior experience in piping, fabrication, welding, construction, or quality control is beneficial but not mandatory.

Who Can Enroll

The OSHAA 30-Hours Professional Diploma in Piping QA/QC Engineer is ideal for individuals seeking advanced knowledge in piping quality assurance and engineering systems.

  • Engineering graduates pursuing QA/QC roles
  • QA/QC professionals aiming to enhance piping expertise
  • Piping and fabrication supervisors seeking quality knowledge
  • Construction engineers involved in compliance monitoring
  • Technical staff transitioning into QA/QC engineering roles
  • Individuals focused on safety, compliance, and technical accuracy

Course Learning Outcomes

Introduction to Piping QA/QC Engineering (2 Hours)

  • Understand the role and responsibilities of a QA/QC engineer in piping projects
  • Recognise the importance of quality assurance and quality control in industrial environments
  • Identify the stages of quality management throughout the piping lifecycle
  • Gain familiarity with essential QA/QC terminology and workflow

Piping Materials, Components, and Fabrication Methods (3 Hours)

  • Identify commonly used piping materials and their characteristics
  • Understand the function of piping components such as flanges, elbows, valves, and gaskets
  • Explain fabrication processes including cutting, welding, bending, and assembly
  • Assess how material selection influences performance, durability, and overall quality

International Codes and Standards: ASME, API, ISO (4 Hours)

  • Interpret the structure and application of international piping standards
  • Apply ASME, API, and ISO codes within quality control and inspection activities
  • Understand compliance requirements across different industrial sectors
  • Evaluate materials and fabrication work against recognised global quality benchmarks

Welding Processes and Procedure Qualification (4 Hours)

  • Understand welding techniques commonly used in piping fabrication
  • Interpret Welding Procedure Specifications (WPS) and Procedure Qualification Records (PQR)
  • Identify common weld defects and understand their causes and effects
  • Ensure welding activities comply with applicable codes and project requirements

Non-Destructive Testing (NDT) Techniques and Applications (4 Hours)

  • Explain the principles and objectives of non-destructive testing in piping systems
  • Identify common NDT methods including radiographic, ultrasonic, magnetic particle, and penetrant testing
  • Select appropriate NDT techniques based on material type, weld configuration, and defect likelihood
  • Interpret NDT results to support quality decisions and compliance reporting

Piping Isometrics and Technical Drawing Interpretation (3 Hours)

  • Read and interpret piping isometric drawings and general arrangement layouts
  • Identify key elements such as line numbers, elevations, weld joints, and material codes
  • Correlate technical drawings with physical installations and inspection requirements
  • Use drawings to plan, execute, and verify QA/QC activities

Inspection and Test Plans (ITPs) in Piping Projects (5 Hours)

  • Understand the purpose and structure of inspection and test plans in quality management
  • Develop ITPs aligned with project scope, codes, and client specifications
  • Define hold points, witness points, and quality control stages within inspection cycles
  • Coordinate with contractors, inspectors, and clients to implement ITPs effectively

Identification of Fabrication Defects and Site Quality Issues (2 Hours)

  • Recognise common fabrication and site-related quality defects
  • Apply inspection techniques to detect issues such as misalignment, corrosion, and unacceptable welds
  • Assess defect severity and recommend appropriate corrective actions
  • Support root cause analysis and continuous quality improvement initiatives

QA/QC Documentation: WPS, PQR, NDT Reports, and Records (3 Hours)

  • Understand the role of quality documentation in piping QA/QC processes
  • Review and verify WPS, PQR, NDT reports, and material certification records
  • Maintain accurate, traceable, and audit-ready inspection documentation
  • Support project handover and compliance audits through effective record management

Frequently Asked Questions (FAQs)

QA/QC ensures that piping systems are fabricated, installed, and inspected according to approved codes and specifications. Proper quality control minimizes risks, enhances safety, and improves long-term system reliability.

Yes, the course introduces basic interpretation of piping drawings and isometric diagrams. This helps learners understand system layouts and inspection checkpoints within projects.

Learners develop skills in inspection planning, defect identification, documentation management, compliance monitoring, and coordination with project teams. The course strengthens both technical understanding and professional confidence.

Piping QA/QC Engineers are highly required in industries such as oil and gas, petrochemical, power generation, marine, and construction. These sectors rely on strict quality control procedures to ensure piping systems operate safely and efficiently.

Yes, participants gain insight into different piping materials, specifications, and material verification procedures. Understanding material standards is essential for maintaining project quality and preventing system failures.

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