This document provides an overview of excavation safety requirements. The primary concern with excavation work is cave-ins, which are more likely to be fatal than other construction accidents. OSHA emphasizes excavation safety through inspections and outreach based on data showing the significant risks. The document reviews requirements for protective systems, soil classification, inspections, protection from hazards, and defining key terms like "competent person" and soil types. The goals are to discuss excavation hazards, protective system requirements, OSHA's soil classification methods, and important definitions.
12 Sheet Piling Operations (Temporary Works) Risk Assessment Templates
Sheet piling Rig checks on arrival to site
PRIOR TO USE
Access of rig and sheet pile delivery vehicles to work areas
Siting and setting up of sheet piling rig
Sheet piling operation
(Mobile rig Operator)
Sheet piling operation
Building Operations and Works of Engineering Construction (Safety) Regulatio...Ahmad Nazib
The document outlines safety regulations for construction work from the Building Operations and Works of Engineering Construction (Safety) Regulation. It covers requirements for machinery safety, prevention of slipping/tripping hazards, electrical safety, protective equipment, scaffolding, ladders, chutes and other equipment. Some key points include:
- Machinery must be safely fenced and floors must support the weight. Passageways must be kept clear of hazards.
- Fall protection such as safety harnesses must be used for high elevations and properly maintained.
- Scaffolding, ladders and other equipment must be sturdily constructed and regularly inspected to ensure safety.
- Chutes used to drop materials must
The document provides a safe work method statement for scaffolding work. It outlines control measures for working platforms, design criteria for erection platforms and temporary edge protection, and a generic work sequence for erecting and dismantling scaffolding. The sequence involves erecting each lift from a fully decked platform below, installing edge protection, and dismantling from the top down by progressively removing materials.
This document provides guidance on excavation and trench safety. It defines excavation, trench, and confined space. The objectives are to highlight excavation hazards, cave-in protection methods, and the role of the competent person. General requirements include locating underground utilities, daily inspections by a competent person, and using protective systems like sloping, shoring, or shielding. Factors in protective system design include soil classification, depth, water content, and other operations. Proper access, egress, and fall protection are also covered.
The document provides information on basic scaffolding, including an introduction, course content, types of scaffolds, scaffolding materials, tools, safety harnesses, and scafftags. The course content section outlines topics that will be covered, including what a scaffold is, different types of scaffolds, materials, tools, safety harnesses, and safe erection and dismantling procedures. It then provides descriptions and details about independent tied scaffolds, putlog scaffolds, bird cage tower scaffolds, roof saddle and stack scaffolds, and suspended scaffolds. The document also lists and describes common scaffolding materials and tools.
This document outlines potential hazards for workers at construction sites and safety measures to address them. It identifies common hazards such as falls from heights, trench collapses, scaffold collapses, and electrical shock. It then provides guidance on safety practices for specific tasks like scaffolding, fall protection, excavations, ladders, and equipment operation. Recommendations include ensuring scaffold and fall arrest systems can support weight, maintaining clear walkways, keeping spoils away from trenches, inspecting lifting equipment for damage, and using proper personal protective equipment. The document emphasizes safety measures for electrical work, traffic control, communication, and first aid preparedness.
Excavation and Trench Safety. Excavation and trenching are amongst the most dangerous operations in the construction industry. Dangers can include cave-ins, falling loads, hazardous atmospheres and hazards from using heavy equipment. Regular pre-work inspections can reduce hazards and serious risk of injury.
This document provides an overview of excavation safety requirements. The primary concern with excavation work is cave-ins, which are more likely to be fatal than other construction accidents. OSHA emphasizes excavation safety through inspections and outreach based on data showing the significant risks. The document reviews requirements for protective systems, soil classification, inspections, protection from hazards, and defining key terms like "competent person" and soil types. The goals are to discuss excavation hazards, protective system requirements, OSHA's soil classification methods, and important definitions.
12 Sheet Piling Operations (Temporary Works) Risk Assessment Templates
Sheet piling Rig checks on arrival to site
PRIOR TO USE
Access of rig and sheet pile delivery vehicles to work areas
Siting and setting up of sheet piling rig
Sheet piling operation
(Mobile rig Operator)
Sheet piling operation
Building Operations and Works of Engineering Construction (Safety) Regulatio...Ahmad Nazib
The document outlines safety regulations for construction work from the Building Operations and Works of Engineering Construction (Safety) Regulation. It covers requirements for machinery safety, prevention of slipping/tripping hazards, electrical safety, protective equipment, scaffolding, ladders, chutes and other equipment. Some key points include:
- Machinery must be safely fenced and floors must support the weight. Passageways must be kept clear of hazards.
- Fall protection such as safety harnesses must be used for high elevations and properly maintained.
- Scaffolding, ladders and other equipment must be sturdily constructed and regularly inspected to ensure safety.
- Chutes used to drop materials must
The document provides a safe work method statement for scaffolding work. It outlines control measures for working platforms, design criteria for erection platforms and temporary edge protection, and a generic work sequence for erecting and dismantling scaffolding. The sequence involves erecting each lift from a fully decked platform below, installing edge protection, and dismantling from the top down by progressively removing materials.
This document provides guidance on excavation and trench safety. It defines excavation, trench, and confined space. The objectives are to highlight excavation hazards, cave-in protection methods, and the role of the competent person. General requirements include locating underground utilities, daily inspections by a competent person, and using protective systems like sloping, shoring, or shielding. Factors in protective system design include soil classification, depth, water content, and other operations. Proper access, egress, and fall protection are also covered.
The document provides information on basic scaffolding, including an introduction, course content, types of scaffolds, scaffolding materials, tools, safety harnesses, and scafftags. The course content section outlines topics that will be covered, including what a scaffold is, different types of scaffolds, materials, tools, safety harnesses, and safe erection and dismantling procedures. It then provides descriptions and details about independent tied scaffolds, putlog scaffolds, bird cage tower scaffolds, roof saddle and stack scaffolds, and suspended scaffolds. The document also lists and describes common scaffolding materials and tools.
This document outlines potential hazards for workers at construction sites and safety measures to address them. It identifies common hazards such as falls from heights, trench collapses, scaffold collapses, and electrical shock. It then provides guidance on safety practices for specific tasks like scaffolding, fall protection, excavations, ladders, and equipment operation. Recommendations include ensuring scaffold and fall arrest systems can support weight, maintaining clear walkways, keeping spoils away from trenches, inspecting lifting equipment for damage, and using proper personal protective equipment. The document emphasizes safety measures for electrical work, traffic control, communication, and first aid preparedness.
Excavation and Trench Safety. Excavation and trenching are amongst the most dangerous operations in the construction industry. Dangers can include cave-ins, falling loads, hazardous atmospheres and hazards from using heavy equipment. Regular pre-work inspections can reduce hazards and serious risk of injury.
6 Excavations (Temporary Works) Risk Assessment Templates
Planned Excavation in areas where live services may be present including:
• Electrical;
• Water;
• Sewerage;
• Gas;
• Telecoms;
PRIOR TO WORKS
Use of Excavator for excavating and backfilling
Excavation open in site area
Confined space working – deep excavations
Maintenance of Excavations
Worker exposure to direct sun
(as applicable)
The document discusses developing and implementing an effective construction safety program, including assigning responsibilities, identifying hazards, providing training, documenting safety rules, setting performance goals, and reviewing incidents to continually improve safety. It also covers establishing emergency response procedures and evaluating contractor safety plans and ongoing project safety.
11 Piling Operations with Rebar Cage installation Risk Assessment Templates
Piling Rig checks on arrival to site
PRIOR TO USE
Access of rig and delivery vehicles to work areas
Siting and setting up of piling rig
Piling operation
(Mobile rig Operator)
Rebar cage fabrication
Pile case and rebar cage lifting operations
This document provides information on scaffolding safety at construction sites. It defines scaffolding and describes the three main types: supported, suspended, and other scaffolds. Supported scaffolds are platforms supported by poles, legs, frames, and outriggers. Suspended scaffolds are platforms suspended by ropes or overhead support. The document outlines general objectives, hazards, and safety requirements for scaffolds. It provides details on inspection of scaffolding components and good and bad safety practices. The overall goal is to educate personnel on scaffolding safety to prevent accidents and injuries at construction sites.
13 Initial Project Site Office Set-up Risk Assessment Templates
Working adjacent to public areas
Vehicles/Plant Equipment movements
Groundworks / excavations
Excavation in site area
Trial trenches, septic tank excavation etc.
Works at Height
(Office cabin set-up)
Use of Ladders and stepladders
Mobile Crane operation
(Cabin/unit placing)
Temporary electrics - offices
Site generators – offices and site
This document outlines the itinerary and content for a scaffolding awareness training course. The course covers introduction and aims, types of scaffolding, component identification, inspection procedures, reasons for collapses, and legislation regarding scaffolding safety. Key topics include health and safety regulations, pre-erection checks, erecting, altering, and dismantling scaffolding safely. The goal is for participants to understand their legal responsibilities for inspecting scaffolding before each use.
This risk assessment document identifies hazards associated with lifting operations using a tower crane on a construction site. It lists 6 specific tasks: 1) access of crane sections, 2) tower crane foundations, 3) siting, setting up and testing, 4) lifting of equipment and material, 5) tower crane supervision, and 6) jumping and dismantling the tower crane. For each task, potential hazards are identified and an initial risk rating is given. Control measures are then provided to reduce the risks, along with any additional measures. Residual risks after controls are also assessed. The goal is to ensure lifting operations are performed safely.
This document provides guidance on fall protection when working at heights. It outlines that falls are a leading cause of death in construction and that fall protection measures should follow a hierarchy of first removing hazards, then using passive barriers like guardrails if work at heights is necessary, and if those are not possible using fall restraint or arrest systems. It details requirements for guardrails, safety nets, harnesses and other fall protection equipment. Situations requiring fall protection include various elevated work areas, openings, excavations and mobile equipment. Ladders, stairs and scaffolding must also be properly constructed and used to prevent falls from any height.
This document provides information on construction safety, with a focus on hot work safety, high risk work safety, and safety tools. It discusses hazards and safety procedures for hot work including welding, gas cutting, and grinding. It also covers high risk work such as work at heights, lifting and rigging, confined space entry, excavation work, and electrical work. It emphasizes the importance of pre-task planning, including job safety analyses, and using permit to work systems to identify hazards and controls before dangerous jobs.
This document provides an overview of fall protection in general industry workplaces. It discusses common fall hazards such as overhead platforms, floor openings, and shelving units. The hierarchy of fall hazard control is presented as eliminating hazards, preventing falls, and controlling falls. Methods of fall protection include guardrails, fall restraint systems, personal fall arrest systems, positioning devices, and safety nets. Employers must provide training on fall hazards and protection methods, inspect workplaces and equipment, and develop rescue plans for personal fall arrest systems.
Concrete Pump checks on arrival to site
PRIOR TO SITE ACCESS
Formwork for slab for temporary support
Falsework to provide temporary support to formwork
Rebar to slabs
Access of mobile pump and delivery trucks to work areas
Siting and setting up of concrete pump
Pumping concrete
(Pump Operator)
Pumping operation supervision
Dismantling of form-work
Striking of false-work
This document provides safety guidelines for operating mounted boom concrete pumps. It lists several hazards to avoid such as booming over wires, maintaining clearance from wires, not relying on depth perception with electric wires, and being aware of overhead power lines. It also recommends proper communication before starting, using clear hand signals, staying out of the boom path, and not exceeding the maximum weight allowed to hang from the boom.
The greatest risk of excavation work is cave-ins. Employees can be protected from cave-ins through the use of protective systems like sloping, shielding, and shoring. A competent person must inspect excavations daily for hazards and ensure protective systems are adequately designed and installed. Other excavation hazards include oxygen deficiency, toxic gases, water accumulation, falls, and mobile equipment.
The document discusses excavation safety. It notes that excavating is one of the most hazardous construction operations, with cave-ins posing the greatest risk and often resulting in fatalities. OSHA regulations require protective systems like sloping, shielding, or shoring for trenches over 5 feet deep. A competent person must inspect sites and determine the appropriate protection. Proper ingress/egress, atmospheric testing, and following basic rules can help prevent accidents and save lives. Pre-planning is critical to excavation safety.
The document discusses the Work at Height Regulations in the UK. It notes that falls from height are a major cause of workplace fatalities and injuries. The regulations were introduced to improve safety by establishing a clear and consistent framework to manage risks associated with working at height. The regulations require hazards to be identified and risks to be properly assessed, controlled, and mitigated through measures such as proper planning, supervision, safe work equipment selection, inspection, and worker training.
The document provides instructions for erecting scaffolding safely. It outlines procedures for selecting a foundation, laying out end pieces and cross braces, installing planks and guardrails. Potential hazards of falling, slips, collapse or being struck by falling objects are discussed. Considerations for tie placement and distances from power lines are covered. Both bad practices like missing guardrails and good practices like using safety belts are shown. Control measures to prevent falls, slips, collapse or falling object injuries are recommended.
This document provides information on scaffolding safety. It defines what a scaffold is and lists common hazards like collapse, falls, and electrocution. It also discusses assessing risks, controlling risks through means like fall protection, and planning scaffolding work. Different types of scaffolds are described, including tower, mobile, tube and coupler, frame, hung, suspended, trestle, and cantilever scaffolds. Load considerations, materials, and safe erection procedures are outlined.
Construction Safety Training_Session 05_Access Equipment and Fall ProtectionMuizz Anibire
Learning Objectives
Identify types of access equipment used in the construction industry.
Identify hazards associated with the use of access equipment.
Describe safety controls and precautions in the use of access equipment.
Describe fall arrest systems used for work at height.
Cave-ins pose the greatest risk in excavations. Employees can be protected from cave-ins through the use of protective systems like sloping, shielding, or shoring. Other excavation hazards include asphyxiation, toxic fumes, fire, machinery near the edge, and severing of utility lines. Proper inspections by a competent person and adherence to safety requirements are needed to protect workers from excavation dangers.
The document provides a resume for Mohammad Hasnat, who has over 14 years of experience as an instrumentation quality and control inspector and engineer. He has worked on numerous projects in Saudi Arabia for companies like Saudi Aramco, conducting inspections and ensuring quality control. His responsibilities included implementing quality plans, inspecting instrumentation installations, preparing reports, and being familiar with international codes and standards. He is seeking new opportunities as an innovative professional who can respond to challenges in the field of instrumentation.
This document is a curriculum vitae for Arman Hussain Khan, who has 18 years of experience in quality control and assurance roles for welding, piping, and painting on oil and gas projects. He currently works as a QA/QC supervisor for Shell BGC in Iraq. He has a diploma in mechanical engineering and certifications in welding inspection, painting inspection, and non-destructive testing. The CV provides details of his roles and responsibilities on various projects in Saudi Arabia, Iraq, India, and the UAE for companies including Shell, WorleyParsons, SK Engineering and Construction, Bilfal Heavy Industries, and Belleli Energy and Saudi Heavy Industries.
6 Excavations (Temporary Works) Risk Assessment Templates
Planned Excavation in areas where live services may be present including:
• Electrical;
• Water;
• Sewerage;
• Gas;
• Telecoms;
PRIOR TO WORKS
Use of Excavator for excavating and backfilling
Excavation open in site area
Confined space working – deep excavations
Maintenance of Excavations
Worker exposure to direct sun
(as applicable)
The document discusses developing and implementing an effective construction safety program, including assigning responsibilities, identifying hazards, providing training, documenting safety rules, setting performance goals, and reviewing incidents to continually improve safety. It also covers establishing emergency response procedures and evaluating contractor safety plans and ongoing project safety.
11 Piling Operations with Rebar Cage installation Risk Assessment Templates
Piling Rig checks on arrival to site
PRIOR TO USE
Access of rig and delivery vehicles to work areas
Siting and setting up of piling rig
Piling operation
(Mobile rig Operator)
Rebar cage fabrication
Pile case and rebar cage lifting operations
This document provides information on scaffolding safety at construction sites. It defines scaffolding and describes the three main types: supported, suspended, and other scaffolds. Supported scaffolds are platforms supported by poles, legs, frames, and outriggers. Suspended scaffolds are platforms suspended by ropes or overhead support. The document outlines general objectives, hazards, and safety requirements for scaffolds. It provides details on inspection of scaffolding components and good and bad safety practices. The overall goal is to educate personnel on scaffolding safety to prevent accidents and injuries at construction sites.
13 Initial Project Site Office Set-up Risk Assessment Templates
Working adjacent to public areas
Vehicles/Plant Equipment movements
Groundworks / excavations
Excavation in site area
Trial trenches, septic tank excavation etc.
Works at Height
(Office cabin set-up)
Use of Ladders and stepladders
Mobile Crane operation
(Cabin/unit placing)
Temporary electrics - offices
Site generators – offices and site
This document outlines the itinerary and content for a scaffolding awareness training course. The course covers introduction and aims, types of scaffolding, component identification, inspection procedures, reasons for collapses, and legislation regarding scaffolding safety. Key topics include health and safety regulations, pre-erection checks, erecting, altering, and dismantling scaffolding safely. The goal is for participants to understand their legal responsibilities for inspecting scaffolding before each use.
This risk assessment document identifies hazards associated with lifting operations using a tower crane on a construction site. It lists 6 specific tasks: 1) access of crane sections, 2) tower crane foundations, 3) siting, setting up and testing, 4) lifting of equipment and material, 5) tower crane supervision, and 6) jumping and dismantling the tower crane. For each task, potential hazards are identified and an initial risk rating is given. Control measures are then provided to reduce the risks, along with any additional measures. Residual risks after controls are also assessed. The goal is to ensure lifting operations are performed safely.
This document provides guidance on fall protection when working at heights. It outlines that falls are a leading cause of death in construction and that fall protection measures should follow a hierarchy of first removing hazards, then using passive barriers like guardrails if work at heights is necessary, and if those are not possible using fall restraint or arrest systems. It details requirements for guardrails, safety nets, harnesses and other fall protection equipment. Situations requiring fall protection include various elevated work areas, openings, excavations and mobile equipment. Ladders, stairs and scaffolding must also be properly constructed and used to prevent falls from any height.
This document provides information on construction safety, with a focus on hot work safety, high risk work safety, and safety tools. It discusses hazards and safety procedures for hot work including welding, gas cutting, and grinding. It also covers high risk work such as work at heights, lifting and rigging, confined space entry, excavation work, and electrical work. It emphasizes the importance of pre-task planning, including job safety analyses, and using permit to work systems to identify hazards and controls before dangerous jobs.
This document provides an overview of fall protection in general industry workplaces. It discusses common fall hazards such as overhead platforms, floor openings, and shelving units. The hierarchy of fall hazard control is presented as eliminating hazards, preventing falls, and controlling falls. Methods of fall protection include guardrails, fall restraint systems, personal fall arrest systems, positioning devices, and safety nets. Employers must provide training on fall hazards and protection methods, inspect workplaces and equipment, and develop rescue plans for personal fall arrest systems.
Concrete Pump checks on arrival to site
PRIOR TO SITE ACCESS
Formwork for slab for temporary support
Falsework to provide temporary support to formwork
Rebar to slabs
Access of mobile pump and delivery trucks to work areas
Siting and setting up of concrete pump
Pumping concrete
(Pump Operator)
Pumping operation supervision
Dismantling of form-work
Striking of false-work
This document provides safety guidelines for operating mounted boom concrete pumps. It lists several hazards to avoid such as booming over wires, maintaining clearance from wires, not relying on depth perception with electric wires, and being aware of overhead power lines. It also recommends proper communication before starting, using clear hand signals, staying out of the boom path, and not exceeding the maximum weight allowed to hang from the boom.
The greatest risk of excavation work is cave-ins. Employees can be protected from cave-ins through the use of protective systems like sloping, shielding, and shoring. A competent person must inspect excavations daily for hazards and ensure protective systems are adequately designed and installed. Other excavation hazards include oxygen deficiency, toxic gases, water accumulation, falls, and mobile equipment.
The document discusses excavation safety. It notes that excavating is one of the most hazardous construction operations, with cave-ins posing the greatest risk and often resulting in fatalities. OSHA regulations require protective systems like sloping, shielding, or shoring for trenches over 5 feet deep. A competent person must inspect sites and determine the appropriate protection. Proper ingress/egress, atmospheric testing, and following basic rules can help prevent accidents and save lives. Pre-planning is critical to excavation safety.
The document discusses the Work at Height Regulations in the UK. It notes that falls from height are a major cause of workplace fatalities and injuries. The regulations were introduced to improve safety by establishing a clear and consistent framework to manage risks associated with working at height. The regulations require hazards to be identified and risks to be properly assessed, controlled, and mitigated through measures such as proper planning, supervision, safe work equipment selection, inspection, and worker training.
The document provides instructions for erecting scaffolding safely. It outlines procedures for selecting a foundation, laying out end pieces and cross braces, installing planks and guardrails. Potential hazards of falling, slips, collapse or being struck by falling objects are discussed. Considerations for tie placement and distances from power lines are covered. Both bad practices like missing guardrails and good practices like using safety belts are shown. Control measures to prevent falls, slips, collapse or falling object injuries are recommended.
This document provides information on scaffolding safety. It defines what a scaffold is and lists common hazards like collapse, falls, and electrocution. It also discusses assessing risks, controlling risks through means like fall protection, and planning scaffolding work. Different types of scaffolds are described, including tower, mobile, tube and coupler, frame, hung, suspended, trestle, and cantilever scaffolds. Load considerations, materials, and safe erection procedures are outlined.
Construction Safety Training_Session 05_Access Equipment and Fall ProtectionMuizz Anibire
Learning Objectives
Identify types of access equipment used in the construction industry.
Identify hazards associated with the use of access equipment.
Describe safety controls and precautions in the use of access equipment.
Describe fall arrest systems used for work at height.
Cave-ins pose the greatest risk in excavations. Employees can be protected from cave-ins through the use of protective systems like sloping, shielding, or shoring. Other excavation hazards include asphyxiation, toxic fumes, fire, machinery near the edge, and severing of utility lines. Proper inspections by a competent person and adherence to safety requirements are needed to protect workers from excavation dangers.
The document provides a resume for Mohammad Hasnat, who has over 14 years of experience as an instrumentation quality and control inspector and engineer. He has worked on numerous projects in Saudi Arabia for companies like Saudi Aramco, conducting inspections and ensuring quality control. His responsibilities included implementing quality plans, inspecting instrumentation installations, preparing reports, and being familiar with international codes and standards. He is seeking new opportunities as an innovative professional who can respond to challenges in the field of instrumentation.
This document is a curriculum vitae for Arman Hussain Khan, who has 18 years of experience in quality control and assurance roles for welding, piping, and painting on oil and gas projects. He currently works as a QA/QC supervisor for Shell BGC in Iraq. He has a diploma in mechanical engineering and certifications in welding inspection, painting inspection, and non-destructive testing. The CV provides details of his roles and responsibilities on various projects in Saudi Arabia, Iraq, India, and the UAE for companies including Shell, WorleyParsons, SK Engineering and Construction, Bilfal Heavy Industries, and Belleli Energy and Saudi Heavy Industries.
THIRTEEN (13.4) years of extensive experience as Mechanical ,Piping , Shutdown project, Material Inspection/Material Prevention in Laydown Area or site area/ Structural QA/QC Inspector & QC Supervisor in Mechanical field of construction in various projects like Oil & Gas Industries, Petro chemicals, Chemical Plants, high rise building and infrastructure sector.
I would like to enroll in your esteemed organization as a candidate for an opening in the field of QA/QC Manager . I expect to here from your end in near future.
Excellent planner and strategist with proven abilities in surveying the projects of all kinds of earth works, power plant, chemical plant, water treatment plant, oil & gas plant etc.
Strong analytical and Organizational abilities with skills to plan and implement novel ideas
Robin Mathew Koshy has over 8 years of experience as a QA/QC welding and piping inspector working on various oil and gas projects in Saudi Arabia. He holds certifications in welding inspection from CSWIP and API, as well as NDT certifications. His responsibilities have included inspection of welding, piping, materials, and coordinating with engineering on projects adhering to international codes and standards. He aims to contribute his skills and experience to a progressive organization.
This document provides a rigging plan for lifting a 72 ton steam drum at a power plant. It details the preparation work, safety responsibilities, lifting procedures, and erection sequence. The drum will be lifted by winch between grid supports that are 18,000mm apart, eliminating the need to tilt the drum. Temporary supports will be installed to guide the strands and provide access platforms for operators during the lift. The electric winch will lift a load of 7 tons on the drum, but exert 35 tons of force on the pulley during the lift.
Workshop on Plant Commissioning and Seamless Startup final.pdfHIMADRI BANERJI
Mr. Himadri Banerji a graduate of the prestigious
Indian Institute of Technology has over 35 years of
industry experience in Steel, Process and Thermal
Power Plants in India and Europe. After a stretch of 22
years in Tata Steel continued his career with such
illustrious companies as Rolls Royce, Torrent and
Reliance. His expertise includes planning, building,
testing, and start up and commissioning, besides
operating and maintaining Large Process Plants, Steel
Plants, Petrochemicals, Dyes and Paints, Cryogenic
Gases, Steam and Electric Power.
Mr. Banerji brings a diverse range of experience in
successful commissioning, having personally led start
up and commissioning teams for plants consisting of
large High Speed Rotary Equipment like Axial and
Radial Compressors, Steam and Gas Turbines, Water
Pumps, Temporary Power Solutions with Medium and
Large Diesel and Gas Engines, Static Systems like
Chemical Reactors, Air Separation Units, Process
Instrumentation and Control, CFBC, AFBC and PF
Steam Generators. His work also encompasses other
Plants like Water Treatment, Effluent Treatment
Plants, Reverse Osmosis and De-mineralising and Desalination
Plants.
He has also recently designed and implemented
chemical regimes for Control of Steam and Water
Cycle Chemistry during Start-up of Super-critical
Power Plants based on Union of the Electricity
Industry – EURELECTRIC guidelines an association of
the Electricity Industry within the European Union.
Dr Banerji regularly chairs and speaks at international
conferences and workshops on Procedures and
Systems for Managing Risk during Start-up and
Commissioning of plants. He has lectured widely in
various countries like Singapore, Malaysia, Indonesia, India
Quality Control & Quality Assurance of MS pipelineIEI GSC
This presentation re. QC & QA of M S pipelines was made at Gujarat State Centre of the Institution of Engineers (India) at Ahmedabad by Er. Manoj Raghavan of SGS (India) Ltd.
This document contains the resume of Sujit Pramanik, including his contact information, education, professional qualifications, work experience, and responsibilities in various roles as a QA/QC engineer and project coordinator on oil and gas projects in India, UAE, and Saudi Arabia. He has over 12 years of experience in inspection roles and is qualified in welding inspection, coating inspection, and non-destructive testing. His experience includes inspection of pipelines, tanks, vessels, and other equipment at both vendor workshops and project sites.
This method statement outlines the safe procedure for removing sharp edges from internal pipe welds using abrasive tools prior to applying a fusion bond epoxy coating. It details the roles and responsibilities of the site engineer, worksite supervisor, and HSE engineer in overseeing the work. The process involves an individual manually entering the pipe using a crawler trolley with rubber wheels to grind away sharp edges and spatters within 12 meters of the pipe end using a pneumatic grinder. Personal protective equipment and ventilation will be used, and inspections will verify completion. Safety measures such as training, permitting, and emergency planning are also described.
The document is a curriculum vitae for Roman B. Carcido, who has over 10 years of experience in QA/QC piping inspection, welding inspection, and welding supervision. He has worked on numerous oil, gas, and industrial projects in Saudi Arabia, the UAE, Qatar, and the Philippines. His duties have included inspecting welding and piping work, ensuring compliance with standards, and supervising inspection teams. He holds many welding and NDT certifications.
This document provides a summary of Pooranam Kirubhakar's professional experience and qualifications. He has over 18 years of experience in quality assurance, welding inspection, and fabrication across various petroleum refineries. He holds several certifications including ASNT Level-III, AWS certified ISO 9001 Lead Auditor, and Nace Certified Level-I Coating Inspector. His experience includes roles as a QA/QC engineer, welding inspector, and RT Level-III technician for numerous projects in India, the Middle East, and Africa.
The document provides a method statement for piping installation works at the Dabbiya site for the Al Dabbiya Phase-1 Additional Injection Wells Tie-Ins project. It outlines the scope of works, sequence of activities, resources, HSE requirements, and emergency contacts. Piping works will involve transporting prefabricated spools to site, lifting them into position, welding field joints, installing valves, and testing. Welding will follow approved procedures and NDT testing. HSE precautions like PPE and fire safety will be enforced during the medium risk work.
The document provides a method statement for piping works at the Dabbiya site for new piping installations at five clusters as part of the Al Dabbiya Phase-1 Additional Injection Wells Tie-Ins project. It outlines the scope of work, references, responsibilities, sequence of works including safety setup, field joint welding, pipe support welding, valve installation and quality control requirements. The piping installations will include welding field joints and assembling prefabricated pipe spools delivered from the workshop.
This curriculum vitae is for Pragash Kannan, who has over 10 years of experience in mechanical, piping, pipeline, construction, and fabrication industries in roles such as quality assurance/quality control inspection engineer, painting inspector, and senior welding inspector in the Middle East. He has a bachelor's degree in mechanical engineering and diplomas in mechanical engineering and AutoCAD. He also holds several professional certifications in welding inspection, piping inspection, and non-destructive testing methods. His career experience includes working as an inspection engineer for Petrofac on a BP project in Iraq and as a senior welding inspector for Punj Lloyd on pipeline projects in Qatar.
POST APPLIED FOR
Any Mechanical / Oil & Gas/ Energy/ Power /Operations and maintenance, WWTP project or industry
• Mechanical Engineer/Supervisor
• QA/QC Engineer/Supervisor
• NDT supervisor
Operations and maintenance, Piping Fabrication, Construction, waste water plane, steel structure, Mechanical , Piping Materials or Plumbing Superintendant , supervisor or Engineer
The document outlines the resume of Mahmoud Mohammed El-Sayes, who is seeking a career with Saudi Aramco where he has over 10 years of experience in quality control and inspection roles in Saudi Arabia and Egypt, including currently serving as a PID Supervisor for Saudi Aramco projects. He provides details of his educational background in mechanical engineering and safety and quality certifications. The resume highlights his responsibilities in roles ensuring quality standards and procedures are followed for various construction and manufacturing projects.
The document provides a summary of the candidate's experience in quality assurance and quality control roles over 6 years, including current and previous positions in welding and painting inspection. It also lists the candidate's qualifications, including engineering and welding certifications, and skills in English communication, adapting to different work environments, and teamwork. The candidate's objective is to secure a challenging position contributing QA/QC skills and helping improve an organization.
The document provides an experience summary and career objective for an individual with 6 years of experience in quality assurance and quality control roles. It details the applicant's work history at various companies in India, the UAE, and Saudi Arabia performing inspections and ensuring compliance with welding, painting, and piping standards. The applicant holds relevant technical certifications and seeks to further their career in quality assurance and control of structural and piping welding.
Harnessing WebAssembly for Real-time Stateless Streaming PipelinesChristina Lin
Traditionally, dealing with real-time data pipelines has involved significant overhead, even for straightforward tasks like data transformation or masking. However, in this talk, we’ll venture into the dynamic realm of WebAssembly (WASM) and discover how it can revolutionize the creation of stateless streaming pipelines within a Kafka (Redpanda) broker. These pipelines are adept at managing low-latency, high-data-volume scenarios.
Using recycled concrete aggregates (RCA) for pavements is crucial to achieving sustainability. Implementing RCA for new pavement can minimize carbon footprint, conserve natural resources, reduce harmful emissions, and lower life cycle costs. Compared to natural aggregate (NA), RCA pavement has fewer comprehensive studies and sustainability assessments.
Batteries -Introduction – Types of Batteries – discharging and charging of battery - characteristics of battery –battery rating- various tests on battery- – Primary battery: silver button cell- Secondary battery :Ni-Cd battery-modern battery: lithium ion battery-maintenance of batteries-choices of batteries for electric vehicle applications.
Fuel Cells: Introduction- importance and classification of fuel cells - description, principle, components, applications of fuel cells: H2-O2 fuel cell, alkaline fuel cell, molten carbonate fuel cell and direct methanol fuel cells.
ACEP Magazine edition 4th launched on 05.06.2024Rahul
This document provides information about the third edition of the magazine "Sthapatya" published by the Association of Civil Engineers (Practicing) Aurangabad. It includes messages from current and past presidents of ACEP, memories and photos from past ACEP events, information on life time achievement awards given by ACEP, and a technical article on concrete maintenance, repairs and strengthening. The document highlights activities of ACEP and provides a technical educational article for members.
Presentation of IEEE Slovenia CIS (Computational Intelligence Society) Chapte...University of Maribor
Slides from talk presenting:
Aleš Zamuda: Presentation of IEEE Slovenia CIS (Computational Intelligence Society) Chapter and Networking.
Presentation at IcETRAN 2024 session:
"Inter-Society Networking Panel GRSS/MTT-S/CIS
Panel Session: Promoting Connection and Cooperation"
IEEE Slovenia GRSS
IEEE Serbia and Montenegro MTT-S
IEEE Slovenia CIS
11TH INTERNATIONAL CONFERENCE ON ELECTRICAL, ELECTRONIC AND COMPUTING ENGINEERING
3-6 June 2024, Niš, Serbia
Redefining brain tumor segmentation: a cutting-edge convolutional neural netw...IJECEIAES
Medical image analysis has witnessed significant advancements with deep learning techniques. In the domain of brain tumor segmentation, the ability to
precisely delineate tumor boundaries from magnetic resonance imaging (MRI)
scans holds profound implications for diagnosis. This study presents an ensemble convolutional neural network (CNN) with transfer learning, integrating
the state-of-the-art Deeplabv3+ architecture with the ResNet18 backbone. The
model is rigorously trained and evaluated, exhibiting remarkable performance
metrics, including an impressive global accuracy of 99.286%, a high-class accuracy of 82.191%, a mean intersection over union (IoU) of 79.900%, a weighted
IoU of 98.620%, and a Boundary F1 (BF) score of 83.303%. Notably, a detailed comparative analysis with existing methods showcases the superiority of
our proposed model. These findings underscore the model’s competence in precise brain tumor localization, underscoring its potential to revolutionize medical
image analysis and enhance healthcare outcomes. This research paves the way
for future exploration and optimization of advanced CNN models in medical
imaging, emphasizing addressing false positives and resource efficiency.
Electric vehicle and photovoltaic advanced roles in enhancing the financial p...IJECEIAES
Climate change's impact on the planet forced the United Nations and governments to promote green energies and electric transportation. The deployments of photovoltaic (PV) and electric vehicle (EV) systems gained stronger momentum due to their numerous advantages over fossil fuel types. The advantages go beyond sustainability to reach financial support and stability. The work in this paper introduces the hybrid system between PV and EV to support industrial and commercial plants. This paper covers the theoretical framework of the proposed hybrid system including the required equation to complete the cost analysis when PV and EV are present. In addition, the proposed design diagram which sets the priorities and requirements of the system is presented. The proposed approach allows setup to advance their power stability, especially during power outages. The presented information supports researchers and plant owners to complete the necessary analysis while promoting the deployment of clean energy. The result of a case study that represents a dairy milk farmer supports the theoretical works and highlights its advanced benefits to existing plants. The short return on investment of the proposed approach supports the paper's novelty approach for the sustainable electrical system. In addition, the proposed system allows for an isolated power setup without the need for a transmission line which enhances the safety of the electrical network
Advanced control scheme of doubly fed induction generator for wind turbine us...IJECEIAES
This paper describes a speed control device for generating electrical energy on an electricity network based on the doubly fed induction generator (DFIG) used for wind power conversion systems. At first, a double-fed induction generator model was constructed. A control law is formulated to govern the flow of energy between the stator of a DFIG and the energy network using three types of controllers: proportional integral (PI), sliding mode controller (SMC) and second order sliding mode controller (SOSMC). Their different results in terms of power reference tracking, reaction to unexpected speed fluctuations, sensitivity to perturbations, and resilience against machine parameter alterations are compared. MATLAB/Simulink was used to conduct the simulations for the preceding study. Multiple simulations have shown very satisfying results, and the investigations demonstrate the efficacy and power-enhancing capabilities of the suggested control system.
Introduction- e - waste – definition - sources of e-waste– hazardous substances in e-waste - effects of e-waste on environment and human health- need for e-waste management– e-waste handling rules - waste minimization techniques for managing e-waste – recycling of e-waste - disposal treatment methods of e- waste – mechanism of extraction of precious metal from leaching solution-global Scenario of E-waste – E-waste in India- case studies.
Optimizing Gradle Builds - Gradle DPE Tour Berlin 2024Sinan KOZAK
Sinan from the Delivery Hero mobile infrastructure engineering team shares a deep dive into performance acceleration with Gradle build cache optimizations. Sinan shares their journey into solving complex build-cache problems that affect Gradle builds. By understanding the challenges and solutions found in our journey, we aim to demonstrate the possibilities for faster builds. The case study reveals how overlapping outputs and cache misconfigurations led to significant increases in build times, especially as the project scaled up with numerous modules using Paparazzi tests. The journey from diagnosing to defeating cache issues offers invaluable lessons on maintaining cache integrity without sacrificing functionality.
Optimizing Gradle Builds - Gradle DPE Tour Berlin 2024
Method Statement of precast pilie and its risk assessment
1. WELCOME TO MY
PRESENTATION
PRESENTATION ON
METHOD STATEMENT OF PRECAST PILING
AND ITS RISK ASSESSMENT
Presented By:
MD.JIHAN RABBANI
ROLL:1423041
COURSE NO:BECM4114
COURSE TEACHER:
Mijanoor Rahman
Jhumana Akter
3. This Specification shall be read in conjunction with all other Contract documents.
Should any queries arise in respect of this Specification, they shall be referred to
the Engineer.
1.PREAMBLES:
2.SCOPE OF THE WORKS
The Piling Contractor will be expected to act as a Sub Contractor.
Main Contractor and will be responsible for the design, supply, delivery and
installation of the piling works.
3.Project Specification
Comply with the latest edition of the BNBC.
4. 4.Existing Services
Contractor shall make enquiries about the position and depth of existing
service pipes, cables and other underground constructions which are likely
to affect the works.
5.Site Inspection
The Piling Contractor will be deemed to have visited and inspected the site
and all surrounding structures roads, services, etc that may be affected by
the piling operations.
6.Site Investigation
A detailed project specific geotechnical investigation has been carried out
and a report issued.
5. 7.Noise & Vibration
The Piling Subcontractor is to allow for and ensure that all measures to control
the noise and vibration levels produced by his operations on site required
under or by virtue of any enactment or regulations, or by the working rules of
any industry, are strictly complied with.
8.Materials
The following materials shall not be built into the works:
Additives containing Calcium Chloride
High alumina cement
Asbestos
Biodegradable void formers
Urea formaldehyde
Calcium silicate bricks
Any other materials known to be deleterious at the time of use.
6. Pile Shoes, Pile Head Reinforcement, Pile Quality, Marking of
Piles, Pile Driving, Pile Installation System, Length of Piles and all
other thing comply with the latest BNBC..
9.Testing
The following tests and rates shall be carried outspread equally across the site;
Dynamic load tests
Static load tests
10.Obstructions
In the event of unnatural obstructions, the Subcontractor shall immediately
inform the Engineer and Main Contractor.
7. RISK ASSESSMENT FOR PILING OPERATIONS
Hazards:
Failure to check manufacturer’s instruction.
Overhead power lines
Underground services not identified.
Inadequate operator training.
Joining pile to existing pile, if deeper piling is necessary.
Unexpected visitors entering the site.
8. CONTROL MEASURES:
Only competent and trained operatives will be allowed to
work with the Piling Rigs.
Always check the manufacturer’s handbook for instructions
regarding the Piling Rig.
Inspect all site maps relating to ground works so as to
identify if there is any underlying services present that need
to be highlighted.