Most popular
B31.3 Process Piping
What you'll learn
Identify the responsibilities of personnel involved in the design, fabrication, assembly, erection, examination, inspection, and testing of process piping
Describe the scope and technical requirements of the ASME B31.3 Code
Apply and implement the quality requirements that are defined in the ASME B31.3 Code
Design of Bolted Flange Joints
What you'll learn
You Will Learn To
Develop an awareness of flange types and the ASME codes and standards applicable for bolted flange joint design
Enhance your knowledge for designing and analyzing bolted flange joints
Explain how the flange design interacts with bolts and gaskets to achieve a leak tight joint
Identify the parameters that can affect flange sealing along with methods to troubleshoot and remediate flange leakage
B31.1 Power Piping
What you'll learn
Identify the difference between “Design by Rule” and “Design by Analysis” codes.
Discover the principal failure modes of piping components and where to look for them.
Recognize the difference between pressure component design and structural design.
Investigate the importance of piping flexibility.
Discuss how to develop stress intensification factors.
Recognize how to qualify nonstandard fittings and joints.
Identify materials selection and limitations, fabrication rules and their bases
Explain welding qualification requirements, inspection, examination, and testing requirements
Identify the Code requirements for power piping maintenance
Fundamentals of Pumps and Their Selection for Optimum System Performance
What you'll learn
Calculate the pressure loss in a pipeline due to friction for circular and non circular ducts
Determine the pipe diameter that minimizes first plus operating costs of a piping system
Generate a system curve for a pipeline
Identify the testing methods used to obtain a performance map for a centrifugal pump
Employ the system curve to select an efficient centrifugal pump
Explain how to predict when cavitation will occur and identify the necessary steps to avoid it
Explain how to use dimensional analysis to correlate experimental data for a pump
Explain how the specific speed is determined
Apply affinity laws to predict off-design behavior for a pump
Identify types of positive displacement pumps
Examine common methods of measuring flow rate in a pipeline
Identify the types of meters available for flow rate measurement
Generate calibration curves for venturi, orifice, and elbow meters
Describe the different types of valves that are commercially available
Explain how to select the correct valve for a piping system
Identify and avoid problems by selecting the correct valve
Explain how to install, operate and maintain valves
Describe the process of diagnosing and troubleshooting valve problems
Featured
Intermediate
ASME BPV Code, Section VIII, Division 2: Design & Fabrication of Pressure Vessels
11,980.00 EGP
ASME BPV Code, Section VIII, Division 2: Design & Fabrication of Pressure Vessels
What you'll learn
Explain how the requirements of Divisions 1 and 2 of Section VIII compare
Explain the theories of failure and design margins of various codes
Identify the general requirements of the new Division 2
Describe design rules and stress analysis methods
Explain fatigue analysis
Identify materials and fabrication requirements
Identify NDE requirements, pressure testing, and pressure relief requirements
Featured
Piping Flexibility and Support
What you'll learn
Paving the way of piping designer to consider code provision.
Provide mandatory introduction to piping stress engineering.
Complete awareness on piping supporting system for construction and maintenance engineers.
B31.8 Gas Transmission & Distribution Piping System
What you'll learn
Explain the causes and modes of pipeline failure
Describe the considerations for material specifications, pipe manufacturing, and pipe joining
Estimate pipeline stresses from external loading
Explain how to evaluate pipeline defects
Identify pipeline repair techniques
Identify the elements of pipeline integrity
Explain how code requirements address these issues
Explain the differences between B31.8 and US DOT gas pipeline regulations
Bolted Joints and Gasket Behavior
What you'll learn
Explain how the bolted joint functions as a mechanical system that relies on the simultaneous interaction of the three primary components to successfully seal the connection
Assess the mechanical stress and strain of a bolt and explain the challenges that one encounters when specifying an optimum bolt load
Evaluate the total state of stress in bolts and how this effects the selection of a given bolt type and grade
Describe the effects of in-service conditions and how they reduce or increase bolt load
Describe the concept of leak tightness as a predictable value of gasket stress and how to use leak tightness as the basis of specifying bolt loads
Identify conditions that create bolt failure
Use ASME PCC-1 Guidelines for compliance to successful sealing of bolted, gasketed connections
Discern how to use either stress or strain to select bolt load
Evaluate the various methods of attaining bolt load.
Featured
ASME B31.12 Hydrogen Piping and Pipelines
What you'll learn
Hydrogen Technologies and Market Players
Global Policies
Describe the scope of B31.12
Explain the design requirements of B31.12
Identify materials requirements
Explain B31.12 requirements for fabrication, assembly, and erection
Explain the B31.12 requirements for inspection, examination, and testing
Trending
B31.3 Process Piping
What you'll learn
Identify the responsibilities of personnel involved in the design, fabrication, assembly, erection, examination, inspection, and testing of process piping
Describe the scope and technical requirements of the ASME B31.3 Code
Apply and implement the quality requirements that are defined in the ASME B31.3 Code
Featured
ASME B31.12 Hydrogen Piping and Pipelines
What you'll learn
Hydrogen Technologies and Market Players
Global Policies
Describe the scope of B31.12
Explain the design requirements of B31.12
Identify materials requirements
Explain B31.12 requirements for fabrication, assembly, and erection
Explain the B31.12 requirements for inspection, examination, and testing
B31.8 Gas Transmission & Distribution Piping System
What you'll learn
Explain the causes and modes of pipeline failure
Describe the considerations for material specifications, pipe manufacturing, and pipe joining
Estimate pipeline stresses from external loading
Explain how to evaluate pipeline defects
Identify pipeline repair techniques
Identify the elements of pipeline integrity
Explain how code requirements address these issues
Explain the differences between B31.8 and US DOT gas pipeline regulations
Design of Bolted Flange Joints
What you'll learn
You Will Learn To
Develop an awareness of flange types and the ASME codes and standards applicable for bolted flange joint design
Enhance your knowledge for designing and analyzing bolted flange joints
Explain how the flange design interacts with bolts and gaskets to achieve a leak tight joint
Identify the parameters that can affect flange sealing along with methods to troubleshoot and remediate flange leakage
Fundamentals of Pumps and Their Selection for Optimum System Performance
What you'll learn
Calculate the pressure loss in a pipeline due to friction for circular and non circular ducts
Determine the pipe diameter that minimizes first plus operating costs of a piping system
Generate a system curve for a pipeline
Identify the testing methods used to obtain a performance map for a centrifugal pump
Employ the system curve to select an efficient centrifugal pump
Explain how to predict when cavitation will occur and identify the necessary steps to avoid it
Explain how to use dimensional analysis to correlate experimental data for a pump
Explain how the specific speed is determined
Apply affinity laws to predict off-design behavior for a pump
Identify types of positive displacement pumps
Examine common methods of measuring flow rate in a pipeline
Identify the types of meters available for flow rate measurement
Generate calibration curves for venturi, orifice, and elbow meters
Describe the different types of valves that are commercially available
Explain how to select the correct valve for a piping system
Identify and avoid problems by selecting the correct valve
Explain how to install, operate and maintain valves
Describe the process of diagnosing and troubleshooting valve problems
B31.1 Power Piping
What you'll learn
Identify the difference between “Design by Rule” and “Design by Analysis” codes.
Discover the principal failure modes of piping components and where to look for them.
Recognize the difference between pressure component design and structural design.
Investigate the importance of piping flexibility.
Discuss how to develop stress intensification factors.
Recognize how to qualify nonstandard fittings and joints.
Identify materials selection and limitations, fabrication rules and their bases
Explain welding qualification requirements, inspection, examination, and testing requirements
Identify the Code requirements for power piping maintenance
Bolted Joints and Gasket Behavior
What you'll learn
Explain how the bolted joint functions as a mechanical system that relies on the simultaneous interaction of the three primary components to successfully seal the connection
Assess the mechanical stress and strain of a bolt and explain the challenges that one encounters when specifying an optimum bolt load
Evaluate the total state of stress in bolts and how this effects the selection of a given bolt type and grade
Describe the effects of in-service conditions and how they reduce or increase bolt load
Describe the concept of leak tightness as a predictable value of gasket stress and how to use leak tightness as the basis of specifying bolt loads
Identify conditions that create bolt failure
Use ASME PCC-1 Guidelines for compliance to successful sealing of bolted, gasketed connections
Discern how to use either stress or strain to select bolt load
Evaluate the various methods of attaining bolt load.
Featured
Intermediate
ASME BPV Code, Section VIII, Division 2: Design & Fabrication of Pressure Vessels
11,980.00 EGP
ASME BPV Code, Section VIII, Division 2: Design & Fabrication of Pressure Vessels
What you'll learn
Explain how the requirements of Divisions 1 and 2 of Section VIII compare
Explain the theories of failure and design margins of various codes
Identify the general requirements of the new Division 2
Describe design rules and stress analysis methods
Explain fatigue analysis
Identify materials and fabrication requirements
Identify NDE requirements, pressure testing, and pressure relief requirements
Expert
What Went Wrong: Case Histories of Process Plant Disasters Learn from accidents. Plant Layout issues
15,000.00 EGP
What Went Wrong: Case Histories of Process Plant Disasters Learn from accidents. Plant Layout issues
What you'll learn
Awareness of how safety has no tolerance.
Provide a way to handle different design issues.
Show the importance of organizing Lessons Learned smart database.
Featured Courses
Featured
Piping Flexibility and Support
Flexibility is a crucial topic in Process Piping Engineering. Almost, …
Piping Flexibility and Support
What you'll learn
Paving the way of piping designer to consider code provision.
Provide mandatory introduction to piping stress engineering.
Complete awareness on piping supporting system for construction and maintenance engineers.
Featured
ASME BPV Code, Section VIII, Division 2: Design & Fabrication of Pressure Vessels
This introductory course describes the use of alternative rules for …
ASME BPV Code, Section VIII, Division 2: Design & Fabrication of Pressure Vessels
What you'll learn
Explain how the requirements of Divisions 1 and 2 of Section VIII compare
Explain the theories of failure and design margins of various codes
Identify the general requirements of the new Division 2
Describe design rules and stress analysis methods
Explain fatigue analysis
Identify materials and fabrication requirements
Identify NDE requirements, pressure testing, and pressure relief requirements
Featured
ASME B31.12 Hydrogen Piping and Pipelines
ASME B31.12 Standard on Hydrogen Piping and Pipelines contains requirements …
ASME B31.12 Hydrogen Piping and Pipelines
What you'll learn
Hydrogen Technologies and Market Players
Global Policies
Describe the scope of B31.12
Explain the design requirements of B31.12
Identify materials requirements
Explain B31.12 requirements for fabrication, assembly, and erection
Explain the B31.12 requirements for inspection, examination, and testing
Popular Topics
Piping
pipeline
Plant Assets.
Hydrogen
Stress
Flexible bellow
Value Management
Spring hanger
Spring Support
Flexible joint
Damper
Process Plant Disasters
Piping Maintenance
Energy Audit
Root Cause Analysis
refinery accidents.
Plant Layout
Flexibility
Lessons Learned
ASME
Piping Procurement
Piping Installation
HAZOP
Quality Management
Energy; Energy management; Energy Efficiency;
Energy systems
RCA
value engineering
Innovation.
Transportation Industry
Wind Turbine
project management
piping workflow
Function Analysis System Techniques
piping schedule
proposal
FAST
Wend Energy
Highway construction
Value Analysis
Renewable Energy
problem solving
SAVE International
Lead Engineer
Value Methodology
Bid
Tender
Construction
All ~ Live Sessions Led by Trainer Courses
Function Analysis Guide
What you'll learn
Provide strong background on Value Engineering in highway and transportation.
Support in establishment of Organization VE program.
Train VE team on program management.
Writing Technical Proposal to attract and win clients
What you'll learn
Understanding the core of your business
Enhancing proposal writing process
Client management
Intermediate
FAST Creativity and innovation, Rapidly Improving Processes, Product Development and Solving Complex Problems
3,500.00 EGP
FAST Creativity and innovation, Rapidly Improving Processes, Product Development and Solving Complex Problems
What you'll learn
Rapidly improving process, product development and solving complex problems
Professional Piping Lead Engineer
What you'll learn
Overview on project management
Setting and achieve success criteria
Piping Lead engineer management approaches
Path forward of Lead Engineer
A Guide to the Value Methodology Body of Knowledge (VM Guide)
What you'll learn
Provide strong background on Value Engineering in highway and transportation.
Support in establishment of Organization VE program.
Train VE team on program management.
Intermediate
Guidelines for Value Engineering in Highway and Transportation Organizations
5,800.00 EGP
Guidelines for Value Engineering in Highway and Transportation Organizations
What you'll learn
Provide strong background on Value Engineering in highway and transportation.
Support in establishment of Organization VE program.
Train VE team on program management.
Wind Energy, from academic and Industrial perspectives
What you'll learn
Shed a light on renewable energy.
Increase trainee awareness for wind energy.
Provide Engineering background on wind turbine design from mechanical and civil perspectives.
Stepping into Piping Engineering – Components
What you'll learn
What is Piping Engineering.
Piping Engineers Roles and Responsibilities.
Detailed study of Piping Network Components.
Energy Management and Efficiency for process plant
What you'll learn
provide a concise overview of energy management principles and techniques for the process industries.
Be aware of international standards relevant to Energy Management.
Train team on program management.
Expert
What Went Wrong: Case Histories of Process Plant Disasters Learn from accidents. Plant Layout issues
15,000.00 EGP
What Went Wrong: Case Histories of Process Plant Disasters Learn from accidents. Plant Layout issues
What you'll learn
Awareness of how safety has no tolerance.
Provide a way to handle different design issues.
Show the importance of organizing Lessons Learned smart database.
Root Cause Analysis, the right tool
What you'll learn
Provide a guide to empirically investigating quality failures using the scientific method in the form of cycles of Plan-Do-Check-Act (PDCA) supported by the use of quality tools.
Intermediate
Piping Resilient Supports. Selection, Spec’s, Procurement, Installation and Maintenance
12,000.00 EGP
Piping Resilient Supports. Selection, Spec’s, Procurement, Installation and Maintenance
What you'll learn
Covers the whole cycle of resilient support, starting by design and ends at maintenance.
Understanding the true function and clear the popular myth.
Change the focus on pipe support from just a member to important asset.
Featured
Piping Flexibility and Support
What you'll learn
Paving the way of piping designer to consider code provision.
Provide mandatory introduction to piping stress engineering.
Complete awareness on piping supporting system for construction and maintenance engineers.
Featured
Intermediate
ASME BPV Code, Section VIII, Division 2: Design & Fabrication of Pressure Vessels
11,980.00 EGP
ASME BPV Code, Section VIII, Division 2: Design & Fabrication of Pressure Vessels
What you'll learn
Explain how the requirements of Divisions 1 and 2 of Section VIII compare
Explain the theories of failure and design margins of various codes
Identify the general requirements of the new Division 2
Describe design rules and stress analysis methods
Explain fatigue analysis
Identify materials and fabrication requirements
Identify NDE requirements, pressure testing, and pressure relief requirements
Featured
ASME B31.12 Hydrogen Piping and Pipelines
What you'll learn
Hydrogen Technologies and Market Players
Global Policies
Describe the scope of B31.12
Explain the design requirements of B31.12
Identify materials requirements
Explain B31.12 requirements for fabrication, assembly, and erection
Explain the B31.12 requirements for inspection, examination, and testing
Fundamentals of Pumps and Their Selection for Optimum System Performance
What you'll learn
Calculate the pressure loss in a pipeline due to friction for circular and non circular ducts
Determine the pipe diameter that minimizes first plus operating costs of a piping system
Generate a system curve for a pipeline
Identify the testing methods used to obtain a performance map for a centrifugal pump
Employ the system curve to select an efficient centrifugal pump
Explain how to predict when cavitation will occur and identify the necessary steps to avoid it
Explain how to use dimensional analysis to correlate experimental data for a pump
Explain how the specific speed is determined
Apply affinity laws to predict off-design behavior for a pump
Identify types of positive displacement pumps
Examine common methods of measuring flow rate in a pipeline
Identify the types of meters available for flow rate measurement
Generate calibration curves for venturi, orifice, and elbow meters
Describe the different types of valves that are commercially available
Explain how to select the correct valve for a piping system
Identify and avoid problems by selecting the correct valve
Explain how to install, operate and maintain valves
Describe the process of diagnosing and troubleshooting valve problems
B31.1 Power Piping
What you'll learn
Identify the difference between “Design by Rule” and “Design by Analysis” codes.
Discover the principal failure modes of piping components and where to look for them.
Recognize the difference between pressure component design and structural design.
Investigate the importance of piping flexibility.
Discuss how to develop stress intensification factors.
Recognize how to qualify nonstandard fittings and joints.
Identify materials selection and limitations, fabrication rules and their bases
Explain welding qualification requirements, inspection, examination, and testing requirements
Identify the Code requirements for power piping maintenance
B31.3 Process Piping
What you'll learn
Identify the responsibilities of personnel involved in the design, fabrication, assembly, erection, examination, inspection, and testing of process piping
Describe the scope and technical requirements of the ASME B31.3 Code
Apply and implement the quality requirements that are defined in the ASME B31.3 Code
Bolted Joints and Gasket Behavior
What you'll learn
Explain how the bolted joint functions as a mechanical system that relies on the simultaneous interaction of the three primary components to successfully seal the connection
Assess the mechanical stress and strain of a bolt and explain the challenges that one encounters when specifying an optimum bolt load
Evaluate the total state of stress in bolts and how this effects the selection of a given bolt type and grade
Describe the effects of in-service conditions and how they reduce or increase bolt load
Describe the concept of leak tightness as a predictable value of gasket stress and how to use leak tightness as the basis of specifying bolt loads
Identify conditions that create bolt failure
Use ASME PCC-1 Guidelines for compliance to successful sealing of bolted, gasketed connections
Discern how to use either stress or strain to select bolt load
Evaluate the various methods of attaining bolt load.
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