This document outlines a rig move management and logistics plan. It addresses personnel requirements, equipment requirements, responsibilities, procedures, and contingency plans for rig moves. Key aspects of the plan include conducting surveys of roads and locations; ensuring communication between locations; conducting safety meetings; establishing loading and unloading procedures; convoy procedures; and pre-departure checks. Inspection procedures are also outlined for cranes, lifting equipment, trucks, and safety meetings for involved personnel.
Permit To Work
Types of Permit To Work
Hot Work Permit
Confined Space Entry Permit
Electrical Permit
Excavation Permit
Radiography Permit
Crane Critical Lifts Permit
Man Basket Operation
Permit Issuer Responsibilities
Permit Receiver Responsibilities
HSE Permit Coordinator
Responsibilities
Revalidation of the Permit
Work Permit Flow Chart
This document provides guidance on planning and performing rigging operations safely. It discusses determining lift requirements and load characteristics, selecting and inspecting rigging equipment like slings and shackles, and procedures for handling different types of loads. Key steps include classifying the lift, checking weight and center of gravity of the load, selecting properly rated rigging gear based on the lift angle and load diameter, and following requirements for ordinary, pre-engineered or critical lifts. Inspection criteria are provided for various rigging components to ensure safety.
This document discusses lifting safety and provides information on various types of lifting equipment. It defines lifting equipment as any work equipment used for lifting and lowering loads, including accessories. Examples of lifting equipment include overhead cranes, hoists, lifts, and slings. The document also discusses chain hoists in detail, outlining the main types (differential, lever ratchet, hand), components, inspection procedures, and safety factors. Annual inspections of lifting equipment are recommended to check for wear, damage, and safety.
This document provides information about cranes and crane safety. It discusses the purpose of crane safety training, the types of cranes commonly used in construction, crane components, OSHA crane standards, assembly and disassembly procedures, hazards associated with cranes, and responsibilities for qualified operators, riggers, and signal persons. The objectives of crane safety training are to understand crane components, hazards, safety procedures, and OSHA regulations to safely operate and work with cranes.
Overhead crane operators must follow proper safety procedures when operating cranes. This includes inspecting equipment daily, not operating cranes with worn or damaged components, and using standard hand signals to communicate with other workers. Operators must be aware of weight limits and safety hazards like swinging loads. Regular inspections of cranes help identify issues to ensure safe operation.
Wireline and slickline are types of cables used downhole in oil and gas wells. Wireline tools have insulated electrical conductors to transmit power and signals, while slickline is a single steel strand. A wireline tool string includes surface units like power packs and wellhead equipment to lower the string, and subsurface units like jars, crossover subs, and gauges that perform downhole functions.
The document discusses Process Safety Management (PSM) systems. It explains that PSM systems are comprehensive management systems used to avoid incidents in hazardous industries like chemical plants. The document outlines the 14 elements of a PSM system, which include employee participation, process hazard analysis, operating procedures, contractor control, training, mechanical integrity, management of change, emergency response planning, and compliance audits. It also provides details on each of the 14 elements and how they work together in a PSM system's plan-do-check-act framework.
Permit To Work
Types of Permit To Work
Hot Work Permit
Confined Space Entry Permit
Electrical Permit
Excavation Permit
Radiography Permit
Crane Critical Lifts Permit
Man Basket Operation
Permit Issuer Responsibilities
Permit Receiver Responsibilities
HSE Permit Coordinator
Responsibilities
Revalidation of the Permit
Work Permit Flow Chart
This document provides guidance on planning and performing rigging operations safely. It discusses determining lift requirements and load characteristics, selecting and inspecting rigging equipment like slings and shackles, and procedures for handling different types of loads. Key steps include classifying the lift, checking weight and center of gravity of the load, selecting properly rated rigging gear based on the lift angle and load diameter, and following requirements for ordinary, pre-engineered or critical lifts. Inspection criteria are provided for various rigging components to ensure safety.
This document discusses lifting safety and provides information on various types of lifting equipment. It defines lifting equipment as any work equipment used for lifting and lowering loads, including accessories. Examples of lifting equipment include overhead cranes, hoists, lifts, and slings. The document also discusses chain hoists in detail, outlining the main types (differential, lever ratchet, hand), components, inspection procedures, and safety factors. Annual inspections of lifting equipment are recommended to check for wear, damage, and safety.
This document provides information about cranes and crane safety. It discusses the purpose of crane safety training, the types of cranes commonly used in construction, crane components, OSHA crane standards, assembly and disassembly procedures, hazards associated with cranes, and responsibilities for qualified operators, riggers, and signal persons. The objectives of crane safety training are to understand crane components, hazards, safety procedures, and OSHA regulations to safely operate and work with cranes.
Overhead crane operators must follow proper safety procedures when operating cranes. This includes inspecting equipment daily, not operating cranes with worn or damaged components, and using standard hand signals to communicate with other workers. Operators must be aware of weight limits and safety hazards like swinging loads. Regular inspections of cranes help identify issues to ensure safe operation.
Wireline and slickline are types of cables used downhole in oil and gas wells. Wireline tools have insulated electrical conductors to transmit power and signals, while slickline is a single steel strand. A wireline tool string includes surface units like power packs and wellhead equipment to lower the string, and subsurface units like jars, crossover subs, and gauges that perform downhole functions.
The document discusses Process Safety Management (PSM) systems. It explains that PSM systems are comprehensive management systems used to avoid incidents in hazardous industries like chemical plants. The document outlines the 14 elements of a PSM system, which include employee participation, process hazard analysis, operating procedures, contractor control, training, mechanical integrity, management of change, emergency response planning, and compliance audits. It also provides details on each of the 14 elements and how they work together in a PSM system's plan-do-check-act framework.
The term Prestartup Safety Review (PSSR) first received prominence in the process industries with the introduction of the Process Safety Management (PSM) regulations.
Chemicals are the most common and significant health hazards and Chemicals can be hazardous for numerous reasons and can combine with other chemicals to make new hazards.
Therefore All hazards must be taken into account when using and storing chemicals.
# Understand that chemicals hazards.
# Understand that safe storage is an important issue.
# Understand that many chemical injuries result from
improper storage.
# Know four basic rules of chemical safety.
# Be aware of the categories of dangerous chemicals
and appropriate safety precautions.
Hydrogen sulfide is one of the most deadly industrial gases especially in oil and gas industry. It has been referred to as a silent killer. This comprehensive PPT covers a wide range of topics including characteristics of H2S, monitoring areas for H2S levels, emergency procedures, hazard minimization, contingency planning, and more. Complete and up-to-date. A great tool for required annual training.
Please understand this is for reference and not for training.
Safety First, Compliance Training is not authorizing the use of this Power
Point Presentation for any purpose other than a review and does not warrant
the content for misrepresentation. Any form of use, wether whole or in part
will constitute violation of this agreement.
You can understand I can not monitor your interpretation of this presentation
and will not be available to defend you not knowing your conversations or
content of class conversations. Please understand.
Feel free to contact us for any other training you maybe in need of for
aerials, skid-steer, forks or other training need you may have.
Regards,
Denise
Denise Almonte
Safety First, Compliance Safety Training
708-977-9106
This document provides information on the safe use, handling, and storage of compressed gases. It discusses regulations, properties of different types of gases, gas behavior, container markings, and emergency response. Key points covered include definitions of compressed, liquefied, and cryogenic gases; gas laws; hazard classifications; and regulations from organizations like OSHA, NFPA, and SDS. Color codes and markings are important for identifying gas types and ensuring safety.
Here are the key points that are wrong in this picture:
- The sling is being choked around a sharp edge, which can cut and damage the sling material over time.
- There is no packing/protection on the sharp edge to prevent damage to the sling as it is lifted. Padding/packing should always be used on sharp edges to protect slings.
- Choking a sling increases the stress on it and reduces its working load limit. It's generally not good practice if it can be avoided.
- The choke may not be balanced/even, putting uneven stresses on different parts of the sling. An uneven choke could cause the sling to fail.
So in summary
This document provides an overview of important factors related to safe lifting operations, including common accidents, legislative requirements, roles of personnel, machinery considerations, and types of lifting gears. It discusses cranes like mobile cranes and tower cranes and safe operation points. It also covers various lifting gears such as wire rope slings, chain slings, hooks, and their inspection and proper use. The document emphasizes the importance of following safety procedures and using qualified personnel and properly inspected equipment to reduce lifting accidents.
The document discusses emergency information panels (EIPs) that must be displayed on vehicles transporting hazardous chemicals. It notes that:
1) EIPs display warning and emergency information, including the chemical name, UN number, hazard class, HAZCHEM code, emergency contact numbers, and special advice.
2) Indian law mandates that vehicles transporting hazardous chemicals display an EIP with specified details.
3) EIPs help emergency response teams properly handle chemical emergencies.
The Rig Safety Awareness course features ten e-learning modules, designed for new technical and petroleum engineers going offshore for the first time. The modules will require between 30 to 40 minutes study each.
Each module will also include assessment questions that relate to module’s content. Each e-learning module will be supported by four 2D ‘Walkthrough Events’ where the user is stepped through a series of safety failures that leed to an incident occurrence.
The document provides guidance on safety procedures for lifting operations using cranes and rigging equipment. Some key points include:
- Proper planning of lifting operations, selection of suitable cranes and equipment, maintenance, training of personnel, and supervision are essential for safety.
- Cranes must be set up correctly with outriggers fully extended on level, stable ground before heavy lifts.
- Rigging such as slings and shackles must be inspected and rated for the load, with the load balanced and secured above its center of gravity.
- Personnel must stand clear of lifts and be protected from potential hazards during the operation.
- Guidelines are provided for safe practices regarding crane operation
This document provides an overview of safety and environmental management practices in the upstream oil and gas industry. It discusses the health, safety, and environmental policy of ONGC, terms used in the industry, causes of accidents, major activities (drilling, production, exploration), and safety practices for each. It also covers risk assessment and analysis, technologies to enhance fire and life safety, and concludes by emphasizing the importance of addressing potential health risks early in project planning processes.
This document provides an introduction to health, safety and environmental issues in the oil and gas industry. It discusses why HSE is important given the high-risk nature of the work and potential for catastrophic accidents. Two examples of major accidents, the Piper Alpha platform explosion and Deepwater Horizon oil spill, are described to illustrate the risks. The document then covers hazard identification and risk assessment processes used in the industry. It provides examples of common hazards and approaches to controlling risks, including the use of engineering solutions, administrative controls and personal protective equipment. Training requirements for workers and definitions of key terms like incidents and near misses are also outlined.
Improper management of highly hazardous chemicals, including toxic, reactive or flammable liquids, can cause accidental releases and emergency responses. OSHA’s Process Safety Management of Highly Hazardous Chemicals standard (29 CFR 1910.119) regulates the management of highly hazardous chemicals. Violations can carry fines of up to $126,000. Do you have a PSM program in place?
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.
Fall hazard means a circumstance that exposes a worker in a workplace to a risk of a fall that is reasonably likely to cause injury to the worker or other person.
Assessing risks from working at height.
Common Fall Hazards at construction site.
Common Scaffold Hazards.
PERSONAL FALL PROTECTION.
Travel-Restraint Systems.
Fall-Arrest Systems.
Lifelines.
Scaffolding, also called scaffold or staging, is a temporary structure used to support a work crew and materials to aid in the construction, maintenance and repair of buildings, bridges and all other man made structures.
This document outlines health and safety topics covered in an induction training. It discusses hazards associated with working at heights, proper use of ladders and scaffolding, fall protection, machine safety, chemical hazards, traffic safety, fire safety, and more. Safety signage and their meanings are explained. Penalties for safety infractions are listed to encourage compliance with safety rules and regulations. The goal is to educate workers on best practices to avoid accidents and injuries on the jobsite.
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.
Health & Safety For Water Treatment Plant OperatorsDavid Horowitz
The document discusses health and safety issues at water treatment facilities. It covers common hazards like slips and falls, strains and sprains, and exposure to toxic gases. It also discusses the Globally Harmonized System for classifying chemicals and communicating hazard information. Physical hazards include flammability and reactivity. Health hazards can be acute like corrosivity or chronic like carcinogenicity. The system standardizes labels, pictograms, and safety data sheets to clearly communicate hazard information. Proper training and a phased implementation process are needed to transition chemical management programs.
Cranes are machines used to lift and move heavy loads and come in several types including mobile, gantry, tower, and mechanical. There are two types of lifting - manual and mechanical using cranes or chain blocks. Different types of lifts include light, heavy, critical, and tandem lifts using two or more cranes. Crane operation can result in deaths from issues like power line contact, rigging failures, structure failures, tipping over, and swing radius crushing. Safety protocols include inspection checklists for rigging and removing damaged slings/ropes from service to prevent failures when lifting loads.
Scaffolding safety is crucial in any construction or maintenance project that requires working at heights. Proper safety measures must be implemented to ensure the safety of workers and prevent accidents.Some of the key scaffolding safety measures include:
Scaffolding should only be erected, altered, or dismantled by a competent person who has received the necessary training.
The scaffolding should be designed and constructed by a qualified engineer or scaffolding designer.
The scaffolding should be inspected regularly by a competent person to ensure it is in good condition and safe for use.
All workers using the scaffolding should be provided with appropriate personal protective equipment (PPE) such as hard hats, safety shoes, and harnesses.
Scaffolding should be stable, level, and adequately braced to prevent collapse or movement.
The scaffolding should have safe access and egress points, such as ladder access, and the access points should be clearly marked and secured.
Workers should be trained in safe working practices, such as not overloading the scaffolding, not leaning over the guardrails, and not working on a wet or slippery surface.
By implementing these measures, scaffolding safety can be ensured, and workers can work safely and efficiently at heights.
This document discusses safe lifting practices and requirements. It defines routine and non-routine lifts and lists potential hazards. Key requirements include developing a lifting plan, appointing competent supervisors, inspecting equipment, and defining roles for crane operators, riggers, and signal persons. Specific safe practices are outlined for preparing loads, attaching slings, and storing/maintaining equipment. Personnel must be trained and lifts must not endanger workers or exceed equipment ratings.
The document provides information on truck crane operation and inspections. It discusses the components and functions of wheel mounted and truck cranes. It also defines key terms like competent person and outlines OSHA and ANSI standards. The document details required inspections for cranes, including frequent daily to monthly checks and more thorough periodic inspections. Inspection procedures include examining the crane structure, control mechanisms, safety devices, ropes, electrical systems and more. Hand signals for crane operation are illustrated and safety rules for crane operators are provided.
The term Prestartup Safety Review (PSSR) first received prominence in the process industries with the introduction of the Process Safety Management (PSM) regulations.
Chemicals are the most common and significant health hazards and Chemicals can be hazardous for numerous reasons and can combine with other chemicals to make new hazards.
Therefore All hazards must be taken into account when using and storing chemicals.
# Understand that chemicals hazards.
# Understand that safe storage is an important issue.
# Understand that many chemical injuries result from
improper storage.
# Know four basic rules of chemical safety.
# Be aware of the categories of dangerous chemicals
and appropriate safety precautions.
Hydrogen sulfide is one of the most deadly industrial gases especially in oil and gas industry. It has been referred to as a silent killer. This comprehensive PPT covers a wide range of topics including characteristics of H2S, monitoring areas for H2S levels, emergency procedures, hazard minimization, contingency planning, and more. Complete and up-to-date. A great tool for required annual training.
Please understand this is for reference and not for training.
Safety First, Compliance Training is not authorizing the use of this Power
Point Presentation for any purpose other than a review and does not warrant
the content for misrepresentation. Any form of use, wether whole or in part
will constitute violation of this agreement.
You can understand I can not monitor your interpretation of this presentation
and will not be available to defend you not knowing your conversations or
content of class conversations. Please understand.
Feel free to contact us for any other training you maybe in need of for
aerials, skid-steer, forks or other training need you may have.
Regards,
Denise
Denise Almonte
Safety First, Compliance Safety Training
708-977-9106
This document provides information on the safe use, handling, and storage of compressed gases. It discusses regulations, properties of different types of gases, gas behavior, container markings, and emergency response. Key points covered include definitions of compressed, liquefied, and cryogenic gases; gas laws; hazard classifications; and regulations from organizations like OSHA, NFPA, and SDS. Color codes and markings are important for identifying gas types and ensuring safety.
Here are the key points that are wrong in this picture:
- The sling is being choked around a sharp edge, which can cut and damage the sling material over time.
- There is no packing/protection on the sharp edge to prevent damage to the sling as it is lifted. Padding/packing should always be used on sharp edges to protect slings.
- Choking a sling increases the stress on it and reduces its working load limit. It's generally not good practice if it can be avoided.
- The choke may not be balanced/even, putting uneven stresses on different parts of the sling. An uneven choke could cause the sling to fail.
So in summary
This document provides an overview of important factors related to safe lifting operations, including common accidents, legislative requirements, roles of personnel, machinery considerations, and types of lifting gears. It discusses cranes like mobile cranes and tower cranes and safe operation points. It also covers various lifting gears such as wire rope slings, chain slings, hooks, and their inspection and proper use. The document emphasizes the importance of following safety procedures and using qualified personnel and properly inspected equipment to reduce lifting accidents.
The document discusses emergency information panels (EIPs) that must be displayed on vehicles transporting hazardous chemicals. It notes that:
1) EIPs display warning and emergency information, including the chemical name, UN number, hazard class, HAZCHEM code, emergency contact numbers, and special advice.
2) Indian law mandates that vehicles transporting hazardous chemicals display an EIP with specified details.
3) EIPs help emergency response teams properly handle chemical emergencies.
The Rig Safety Awareness course features ten e-learning modules, designed for new technical and petroleum engineers going offshore for the first time. The modules will require between 30 to 40 minutes study each.
Each module will also include assessment questions that relate to module’s content. Each e-learning module will be supported by four 2D ‘Walkthrough Events’ where the user is stepped through a series of safety failures that leed to an incident occurrence.
The document provides guidance on safety procedures for lifting operations using cranes and rigging equipment. Some key points include:
- Proper planning of lifting operations, selection of suitable cranes and equipment, maintenance, training of personnel, and supervision are essential for safety.
- Cranes must be set up correctly with outriggers fully extended on level, stable ground before heavy lifts.
- Rigging such as slings and shackles must be inspected and rated for the load, with the load balanced and secured above its center of gravity.
- Personnel must stand clear of lifts and be protected from potential hazards during the operation.
- Guidelines are provided for safe practices regarding crane operation
This document provides an overview of safety and environmental management practices in the upstream oil and gas industry. It discusses the health, safety, and environmental policy of ONGC, terms used in the industry, causes of accidents, major activities (drilling, production, exploration), and safety practices for each. It also covers risk assessment and analysis, technologies to enhance fire and life safety, and concludes by emphasizing the importance of addressing potential health risks early in project planning processes.
This document provides an introduction to health, safety and environmental issues in the oil and gas industry. It discusses why HSE is important given the high-risk nature of the work and potential for catastrophic accidents. Two examples of major accidents, the Piper Alpha platform explosion and Deepwater Horizon oil spill, are described to illustrate the risks. The document then covers hazard identification and risk assessment processes used in the industry. It provides examples of common hazards and approaches to controlling risks, including the use of engineering solutions, administrative controls and personal protective equipment. Training requirements for workers and definitions of key terms like incidents and near misses are also outlined.
Improper management of highly hazardous chemicals, including toxic, reactive or flammable liquids, can cause accidental releases and emergency responses. OSHA’s Process Safety Management of Highly Hazardous Chemicals standard (29 CFR 1910.119) regulates the management of highly hazardous chemicals. Violations can carry fines of up to $126,000. Do you have a PSM program in place?
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.
Fall hazard means a circumstance that exposes a worker in a workplace to a risk of a fall that is reasonably likely to cause injury to the worker or other person.
Assessing risks from working at height.
Common Fall Hazards at construction site.
Common Scaffold Hazards.
PERSONAL FALL PROTECTION.
Travel-Restraint Systems.
Fall-Arrest Systems.
Lifelines.
Scaffolding, also called scaffold or staging, is a temporary structure used to support a work crew and materials to aid in the construction, maintenance and repair of buildings, bridges and all other man made structures.
This document outlines health and safety topics covered in an induction training. It discusses hazards associated with working at heights, proper use of ladders and scaffolding, fall protection, machine safety, chemical hazards, traffic safety, fire safety, and more. Safety signage and their meanings are explained. Penalties for safety infractions are listed to encourage compliance with safety rules and regulations. The goal is to educate workers on best practices to avoid accidents and injuries on the jobsite.
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.
Health & Safety For Water Treatment Plant OperatorsDavid Horowitz
The document discusses health and safety issues at water treatment facilities. It covers common hazards like slips and falls, strains and sprains, and exposure to toxic gases. It also discusses the Globally Harmonized System for classifying chemicals and communicating hazard information. Physical hazards include flammability and reactivity. Health hazards can be acute like corrosivity or chronic like carcinogenicity. The system standardizes labels, pictograms, and safety data sheets to clearly communicate hazard information. Proper training and a phased implementation process are needed to transition chemical management programs.
Cranes are machines used to lift and move heavy loads and come in several types including mobile, gantry, tower, and mechanical. There are two types of lifting - manual and mechanical using cranes or chain blocks. Different types of lifts include light, heavy, critical, and tandem lifts using two or more cranes. Crane operation can result in deaths from issues like power line contact, rigging failures, structure failures, tipping over, and swing radius crushing. Safety protocols include inspection checklists for rigging and removing damaged slings/ropes from service to prevent failures when lifting loads.
Scaffolding safety is crucial in any construction or maintenance project that requires working at heights. Proper safety measures must be implemented to ensure the safety of workers and prevent accidents.Some of the key scaffolding safety measures include:
Scaffolding should only be erected, altered, or dismantled by a competent person who has received the necessary training.
The scaffolding should be designed and constructed by a qualified engineer or scaffolding designer.
The scaffolding should be inspected regularly by a competent person to ensure it is in good condition and safe for use.
All workers using the scaffolding should be provided with appropriate personal protective equipment (PPE) such as hard hats, safety shoes, and harnesses.
Scaffolding should be stable, level, and adequately braced to prevent collapse or movement.
The scaffolding should have safe access and egress points, such as ladder access, and the access points should be clearly marked and secured.
Workers should be trained in safe working practices, such as not overloading the scaffolding, not leaning over the guardrails, and not working on a wet or slippery surface.
By implementing these measures, scaffolding safety can be ensured, and workers can work safely and efficiently at heights.
This document discusses safe lifting practices and requirements. It defines routine and non-routine lifts and lists potential hazards. Key requirements include developing a lifting plan, appointing competent supervisors, inspecting equipment, and defining roles for crane operators, riggers, and signal persons. Specific safe practices are outlined for preparing loads, attaching slings, and storing/maintaining equipment. Personnel must be trained and lifts must not endanger workers or exceed equipment ratings.
The document provides information on truck crane operation and inspections. It discusses the components and functions of wheel mounted and truck cranes. It also defines key terms like competent person and outlines OSHA and ANSI standards. The document details required inspections for cranes, including frequent daily to monthly checks and more thorough periodic inspections. Inspection procedures include examining the crane structure, control mechanisms, safety devices, ropes, electrical systems and more. Hand signals for crane operation are illustrated and safety rules for crane operators are provided.
This document outlines safety precautions and procedures for crane operations. It establishes requirements for organizing a crane and rigging group with defined roles and responsibilities. It requires crane operators and signalmen to be qualified and trained. It specifies guidelines for crane set up and operation including following approved lift plans, permit requirements, and stopping work if unsafe conditions arise. It defines critical lifts and provides examples. It lists safety precautions for crane and rigging equipment inspections, defects, capacity markings, and color coding for monthly inspections.
This document provides a crane lifting plan and risk assessment for a lifting operation. It details the crane and lift information, including load details, lifting tackle, and crane setup procedures. Safety procedures are outlined, such as conducting a site inspection, briefing personnel, establishing communication methods, and following weather restrictions. Personnel qualifications and roles are defined. The plan is intended to ensure the lifting operation is carried out safely in compliance with relevant standards and regulations.
This document provides guidance on aerial lift safety. It outlines training requirements for operating aerial lifts, as well as inspection requirements. It describes safe work practices for using aerial lifts, including pre-start inspections, hazard assessments of work areas, fall protection, and load capacity limits. The document also summarizes an accident where an employee fell from an aerial lift basket and was killed, and provides recommendations to prevent similar accidents.
Mechanical handling refers to the use of mechanical devices to load, unload, and move goods within a work area. There are various types of mechanical equipment used for this purpose, including cranes, powered industrial trucks, and conveyors. Cranes in particular come in many forms, such as mobile cranes, fixed cranes, overhead cranes, and tower cranes. It is important that all mechanical equipment is properly inspected and maintained to ensure safety. Operators must be trained and follow safety procedures, such as heeding signals, to prevent accidents and injuries when using this type of machinery.
This document provides a summary of Rickie Gerard Christie's qualifications and experience for an oil and gas position. It outlines his 14 years of experience operating casing/tubing tongs and tubular handling equipment. It also details his education in Bachelor of Arts and skills in mechanical aptitude, QHSE procedures, communication, and computer software. Finally, it lists his extensive experience with various tongs, power units, elevators, and other oilfield equipment from his roles as a floorman, roustabout pusher, crane operator, and trainee marine engineer over his career.
The document provides recommendations for safe lifting practices on board ships to ensure safety of personnel and equipment. Key recommendations include:
1. Ensuring lifting plants are of adequate design, construction, strength and free of defects for their intended use and properly maintained through preventive maintenance and inspection.
2. Operating lifting plants safely within their rated capacity and only by authorized and trained personnel.
3. Taking precautions like secure anchoring and positioning of counterweights to ensure stability during lifting and clearly marking controls.
4. Reporting any lifting equipment defects immediately and properly overhauling and testing lifting gear on a regular schedule.
The document provides safety training information for crane and hoist operators. It discusses qualifications required, daily inspection requirements, safety rules to follow during operation, and references various industry standards. The key points are:
- Operators must be qualified through training and pass a practical exam on the specific equipment.
- Daily inspections of hooks, wire ropes, brakes and other components are required to check for any defects or damage.
- Safety rules address proper load handling, not exceeding capacity, following signals, and shutting off power when not in use.
- References provided include ASME and OSHA standards on cranes, hoists, slings and other lifting equipment. Proper inspection and following industry
Overhead Crane Safety Training purpose.pdfssusere30a9a
This document provides an overview of overhead crane safety and prevention training. It covers crane basics like types of cranes and their parts. It discusses inspecting and maintaining cranes, with specific guidance on wire rope inspections. The document outlines crane safety communication tools like warning devices, signs, and standard hand signals. It also covers safe crane operational procedures such as loads, testing, operator qualifications, and conduct. The training is meant to help prevent machine breakdowns and accidents.
The document provides information on safety requirements for various lifting equipment including cranes, derricks, conveyors, elevators, hoists, material hoists and personnel hoists. It discusses general requirements, hazards, inspections, safety practices, and regulations regarding their operation. Major topics covered include crane types, preventing accidents, electrical hazards, suspended platforms, and hoisting personnel. The purpose is to inform about pertinent codes and regulations to safely operate this machinery.
This document provides guidance on overhead crane safety. It outlines requirements for daily operator inspections, including checking the hook, wire rope, control devices and runway systems. Periodic inspections by a qualified person are also required, with frequencies ranging from quarterly to annually depending on crane use. Operational safety procedures are reviewed, such as following signal instructions, maintaining clear views, and not overloading. Recommended forms include a maintenance log, checklists, and training questionnaires. Standard hand signals for crane operations are also presented.
Quality Control Operator Training &.pptxAizazFarhat3
The document provides training information for crane operators, including their responsibilities and safety hazards. It discusses proper inspection and maintenance of cranes, as well as safe operating procedures like ensuring clear communication during lifts, level ground support, and keeping people clear of loads. Hazards mentioned include power lines, overloading, instability, and lack of training or maintenance. Trainees are tested to identify unsafe conditions in images.
This document provides safety guidelines for working with various types of construction machinery. It outlines requirements for siting machinery safely, fencing dangerous parts, providing safe access, and conducting maintenance and inspections. Specific guidelines are provided for earth moving, lifting, and hoisting machinery. Drivers and signalers must be trained and competent. Machinery must be tested regularly and thoroughly inspected for defects before each shift to ensure safe operation.
Crane & Lifting Safety.ppt Crane lifting safety useful for construction industryRamana Reddy G
Major causes of crane accidents include contact with power lines, overturns, falls, and mechanical failures. Accidents commonly occur due to lack of communication between the operator and others involved in the lift, lack of training, instability of the load or ground, and inadequate maintenance or inspection. Proper planning, training, inspection, and following safety procedures can help prevent crane accidents.
This document outlines safety procedures for tower crane operators. It discusses qualifications for operators, required permits and training. It provides details on pre-shift inspection checks, personal protective equipment requirements, standard hand signals, and general safety conduct including not carrying loads over people and following signals. It also covers crane inspection procedures done monthly or quarterly, and maintenance responsibilities.
Project Name: xxx
RA Ref No.: xxx
RA compilation Date: Review date:
Date:
Compiled by:
Reviewed by:
Approved by:
Overall Task Details
Lifting operations using Tower crane within site boundary Relevant Applicable MAS:
• 01412 – Lifting Operations;
• 00941 – Lifting equipment Additional Training required:
Riggers / Slingers NOC’s Required for task:
As applicable
RISK SCORE CALCULATOR
Use the Risk Score Calculator to Determine the Level of Risk of each Hazard
What would be the
CONSEQUENCE
of an occurrence be? What is the LIKELIHOOD of an occurrence? Hierarchy of Controls
Frequent/Almost certain (5)
Continuous or will happen frequently Often (4)
6 to 12 times a year Likely (3)
1 to 5 times a year Possible (2)
Once every 5 years Rarely (1)
Less than once every 5 years Can the hazard be Eliminated or removed from the work place?
Catastrophic (5)
Multiple Fatalities High 25 High 20 High 15 Medium 10 Medium 5 Can the product or process be substituted for a less hazardous alternative?
Serious (4)
Class 1 single fatality High 20 High 16 High 12 Medium 8 Low 4 Can the hazard be engineered away with guards or barriers?
Moderate (3)
Class2 (AWI or LTI) or Class 1 Permanently disabling effects High 15 High 12 Medium 9 Medium 6 Low 3 Can Administration Controls be adopted
I.e. procedures, job rotation etc.
Minor (2)
Medical attention needed, no work restrictions. MTI Medium10 Medium 8 Medium 6 Low 4 Low 2 Can Personal Protective Equipment & Clothing be worn to safe guard against hazards?
Insignificant (1)
FAI Medium10 Medium 4 Low 3 Low 2 Low 1
No Specific Task Step
(In sequence of works) Hazard Details Consequence/Risk Initial Risk Rating Control Measures Residual Risks Additional Control Measures RR
P S RR
1 Access of Tower crane sections to work areas
• Plant and workers in same working area as delivery truck; • Collision with plant or vehicles and live traffic;
• Workers struck by plant, very high risk of fatality;
• Uncontrolled crane reversing; 3 4 12 High i. Worker pedestrian routes to be designed and implemented with clear signage to provide segregation;
ii. Instruction to workers at induction on use of access routes around the project;
iii. Flagmen to be used to control crane movements;
iv. The Logistics plan shall clearly illustrate crane access and egress points; Workers not complying with flagmen Regular topic in TBT’s Low
2 Tower crane foundations • Excavations;
• Use of plant – excavators etc.;
• Use of concrete;
• Temporary Works; • See Risk Assessment 010 – Excavations;
• See Risk Assessment 014 – use of Mobile Concrete pump;
• Failure due to incorrect design; 4 5 20 High i. Crane foundations to be designed by approved persons, to clear design criteria;
ii. Foundations given adequate curing time before crane erection;
iii. Temporary Works Coordinator to control excavations and concrete pours; Low
3 Siting, setting up and testing of Tower crane • Works at Height;
• Working in proximity to existing struct
This document provides an overview of rigging basics and safety. It discusses common rigging hazards like falls, being struck by loads, and electrical hazards. It describes rigging equipment like slings, chains, wire rope, and webbing and requirements for inspecting them. The document outlines qualifications for riggers and crane operators and covers topics like load capacities, hitches, communication signals, and OSHA standards for rigging.
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Rig Move Management and Logistics Plan.doc
1. Rig Move Management & Logistics Plan
Introduction: This Rig Move Plan & Check List will address the personnel requirements, equipment requirements, responsibilities, specific procedures and contingency plans.
General Planning
KERUI HSE will conduct a road and new location survey prior to the movement of any equipment – Map to be drawn, areas of concern will be identified.
KERUI will provide senior personnel positioned at both the current Drilling Location and the New Drilling Location.
KERUI radio and telephone contact will be ensured and between both locations
KERUI will complete equipment Load List by priority. The equipment & materials load list will be on an as need - first required – last required basis.
KERUI will identify equipment Load types by hazard or by weight i.e. heavy Loads – Wide Loads – Dangerous Goods.
KERUI will ensure all Cranes have been properly certified by a recognized inspection organization
KERUI will complete an inspection of all Cranes prior to acceptance – the inspection is to be recorded with all inspection items listed and checked
KERUI will conduct Safety Meetings with all involved KERUI supervisory and general labor prior to rig down and load of vehicles.
KERUI will conduct Safety Meetings with all Crane Operators & Truck Drivers prior to rig down and load of vehicles.
KERUI will conduct Safety Meetings with all Truck Drivers and assigned Sub Contractor Truck Pushes prior to rig down and load of vehicles.
KERUI will conduct Safety Meetings or Tool Box Talks as required.
Daily KERUI Crew meetings will continue
Daily Crew meetings will occur with KERUI Yemeni Subcontractor staff – translation for Arabic Speakers to be provided – Safety Forms to be signed.
Loading & Unloading Procedures
Establish requirements and confirm competence and suitability of supervisors, labor and hardware.
Gross weight to be known for each lift
Certified slings and associated equipment identified and allocated for lift.
All Lifting equipment to be inspected and suitable for each lift – non certified lifting equipment to be removed and destroyed.
Banks man or signalman competent for the task dedicated for each lift
Where possible Trucks will back under or out from under the lift to reduce crane movement - in particular for heavy and decidedly complicated lifts
Conduct Pre Job Safety meeting prior to each days lifting and/or tool Box Talk prior to any Heavy or Tandem Lifts, or Lifts requiring a permit.
Establish Convoy Procedures
Distance between trucks will average 10 meters
Speed limits will be established at 40 KMPH maximum
Conduct Pre Job Safety meeting – as required
Pre-departure Checks
Loads in correct position on vehicles and properly secured. I.e. chain and boomers
Trucks full fueled, drivers prepared drivers prepared with clear directions
Convoy requirements understood
Road hazards identified
Contingencies in place and understood
Conduct Pre Job Safety meeting – as required
2. Rig Move Management & Logistics Plan
Rig Equipment & Materials Logistics Register
New Location Offloading and Rig up Crew
Name Position Signature
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Old Location Loading Crew
Name Position Signature
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3. Rig Move Management & Logistics Plan
Pre-Job Safety Meeting – Rig Crews Groups # 1 & # 2
No. Name Position Signature
Correct PPE – boots, coveralls, hardhat, gloves & hardhat.
Safety Belts and Harness to be worn for working at heights.
Signal man / Banks man identified and known.
Proper communication with Load Master and Rig Manager
No personnel to ride on loads.
Use Tag Lines for all lifts.
Do not stand or walk under suspended loads.
Do not leave loads unattended at any time.
Avoid sharp bends in slings – set loads on blocking and
never set loads directly on slings
Check the SWL of all slings, chains, wire rope before using.
Inspect all rigging equipment prior to use.
Hand signals understood.
Emergency Stop Signal understood
Operator to obey only one rigger or signalman.
Immediately discard defective lifting equipment
Do not tie knots in sling chain, rope slings or wire rope
Do not use rope for rigging or lifting loads
At any time rig personnel can stop or suspend work if the
situation appears unsafe.
Pre-job safety meeting or Tool Box Talks to be conducted on
an as need basis
Stop Cards to be completed during rig moves
All accidents and near misses t be reported
Permits to be used for heavy lifts or tandem lifts.
1 Yu Xiang Dong R.M
2 Li Yanhao Electrician
4 Zhao Tinghai Mechanic
5 Shang Taigang Chief Motorman
6 You Shui Engineer
7 Xu Binhe HSE Officer
8 Lei Yong T.P
10 Tian Chao Driller
11 Liu Bo Driller
12 Ma Wenming Camp Boss
13 Moman Mansour Shakir Welder Man
14 Mohamed Jassem
Mohamed
F.L Op.
15 Mohammed Ali Wali F.L Op.
16 Ali Khalel Crane Op.
17 Latif Crane Op.
18 Sahar Kqdhim mouly A.D
19 Salah Derrickman
20 Hashim Derrickman
21 Hussin Floorman
22 Kadhum Kader Floorman
23 Hussin Abdul khalid Roustabout
24 Ali Naaim Roustabout
25 Msiar Muazi Roustabout
26 Waleed A.D
27 Ather Abdul Sanad Derrickman
28 Ali Mahdi Derrickman
Additional Items or Comments: H
Meeting Chairman Signature: Date:
4. Rig Move Management & Logistics Plan
Pre Rig Move Crane Safety Inspection Procedures
Purpose of the Guideline
The purpose of the guideline is to describe the extent to which contractor and subcontractor-operated cranes, including those which are owned, rented, or leased, shall be inspected
prior to the start of Rig Move activities. General inspections will occur at the beginning of each workday or shift.
Definition and Purpose of Inspections
The Pre-Rig Move safety inspection of sub-contractor-operated cranes comprises brief visual and operational examinations of specified accessible components to determine that
the cranes are safe to operate.
Recording Inspections
The Pre-Rig-Move and daily safety inspections of cranes shall be recorded on the KERUI Log of Daily Crane Safety Inspections.
Detection of any crane safety deficiency shall be recorded on the log, whether the deficiency is corrected immediately or at some other time during the workday or shift. The
deficiency shall be reported immediately to the KERUI Supervisor in charge, and subsequently to Presage Drilling.
Log entries in the date blocks shall be as provided on the form. If more than one deficiency must be noted in the block, place an asterisk in the block and one after Dated
Comments;
Retention and Distribution of Completed Logs
The current and last completed log shall be kept in an envelope in the crane cab.
Additional forms are should be available upon request from KERUI and the Crane Sub Contractor Company.
Original copies of completed logs are to be entered in the KERUI Safety Register - it is advisable to keep the original copies because due to critical entries such as first indication of
wire rope wear or subsequent further deterioration.
Classification and Correction of Deficiencies
Serious
Definition: A deficiency which does not render any part of the crane unsafe, but does indicate the development of a more serious unsafe condition.
Action: Required to be closely re-inspected during each daily safety inspection of the crane to the extent necessary to properly evaluate the deficiency.
Non-Serious
Definition: A deficiency which, in the event the operation of the crane is continued, serious injury or damage is unlikely.
Action: Prior to the end of the work day or shift, inform the responsible supervisor, who shall issue appropriate instructions for corrections of the deficiency.
Minor
Definition: A deficiency which does not render any part of the crane unsafe, but does indicate the development of a more serious unsafe condition.
Action: Required to be closely re-inspected during each daily safety inspection of the crane to the extent necessary to properly evaluate the deficiency.
5. Rig Move Management & Logistics Plan
Crane Safety Inspection Procedures
General Inspection Requirements
Structural:
Inspect outriggers, main and jib boom for damage or malfunction.
Operationally inspect outriggers for proper response to controls and for unhindered full extension and set.
Visually inspect accessible areas of lattice booms of bent or broken members and for missing pin-keepers.
Operationally inspect box-type booms for malfunctions in all movements and for evidence of binding and hydraulic system leaks.
Wire rope and reeving running lines for damage or wear; reeving for correctness.
Limit visual inspection to that portion required for the reeving on the crane. Un-inspected portions should be inspected when different reeving requires additional line.
Running lines must be observed during regular operation to detect occurrences of any damage, excessive twisting, and incorrect reeling.
Known minor deficiencies must be closely reexamined visually during each inspection to determine if further deterioration has occurred.
Newly arrived cranes, and those which are last operated by others, must be visually examined to determine that the reeving is in accordance with the crane manufacturer’s
specifications.
Hooks: Cracks or distortions. Blocks: Cracks in housing, binding swivel, broken or worn sheaves.
Visually examine hooks for evidence or indication of cracks and distortions; if a hook has a visible twist, spread or crack, the responsible supervisor must be notified
immediately, and the hook shall not be used until approved or replaced.
Visually examine all blocks for cracks, binding swivels, and broken or critically worn sheaves; evidence of any of these requires that the responsible supervisor be notified
immediately, and that block shall not be used until approved or replaced.
Electrical Systems: Malfunctions
Visually inspect all readily accessible exposed wiring and switches for damage.
Visually inspect all external headlamps, signal, and running lights for damaged or broken lenses; test all lights for operability.
Actuate each manual electrical switch to determine that it operates as required by energizing the electrical device, light, or signal which it controls.
Safety Devices and Indicators: Hook latch, boom angle indicator, backup alarm, etc., for correct operation.
Visually examine each hook latch for operability, alignment, and proper contact of the latch with the inside face of the hook.
Observe movements of the boom angle indicator to determine that it operates properly throughout its operational range as designed for the crane.
Actuate backup alarms to determine operability and proper response to controls or movements of the crane.
Air and Hydraulic Systems: Leaks, damage and deterioration. Visually inspect all readily accessible air and hydraulic lines, hoses, and fittings for evidence of leaks, damage
or deterioration.
Air systems: Observe gauges for steady drop of pressure; listen for the sound of escaping air which could indicate damage or loose fittings; visually examine observable
abraded, dented, or cut lines and hoses.
Hydraulic systems: Visually inspect accessible hoses for leaks through the hoses and fittings; visually inspect accessible hoses and fittings for cuts, abrasions, twists,
pinches, burrs, and abnormal enlargements.
Controls: Wear, lubrication, adjustments, and interference.
Manipulate each control to detect malfunctions, and lack of proper response of equipment to control movements.
Visually examine accessible control components for interference and lack of proper lubrication.
Miscellaneous:
Tires for under inflation and severe cuts, steps and handholds for damage, critical dents in carrier, cracks or broken windows, etc. The malfunction or damage of any readily
visible or accessible component of the crane which is not included elsewhere in the log should be included in this section.
6. Rig Move Management & Logistics Plan
Crane Safety Pre-move Inspection Procedures
Inspection Protocols OK Minor-comments Non-Serious-comments Serious-comments
1 Outriggers – fully extended
2 Lattice booms
3 Box-type booms
4 Wire rope and reeving running lines
5 Running lines – while crane is active
6 Hooks: Cracks or distortions
7 Blocks: Cracks in housing, binding swivel, broken or worn
sheaves
8 Visually examine all blocks for cracks, binding swivels, and
broken or critically worn sheaves
9 Accessible exposed wiring and switches for damage
10 External headlamps, signal, and running lights
11 Manual electrical switches to determine that it operates as
required by energizing the electrical device, light, or signal
12 Safety Devices and Indicators: Hook latch, boom angle
indicator, backup alarm
13 Visually examine each hook latch for operability, alignment,
and proper contact of the latch
14 Observe movements of the boom angle indicator to
determine that it operates properly
15 Actuate backup alarms
16 Air and Hydraulic Systems: Leaks, damage and deterioration
17 Air systems: Observe gauges for steady drop of pressure;
listen for the sound of escaping air
18 Hydraulic systems: Visually inspect accessible hoses and
fittings.
19 Manipulate each control to detect malfunctions
20 Visually examine accessible control components
21 Tires for under inflation and severe cuts
22 Steps and handholds for damage
23 Critical dents in carrier
24 Cracks or broken windows
25 Malfunction or damage of any readily visible or accessible
component of the crane which is not included elsewhere in
the log
Inspected by: Signature: Date:
7. Rig Move Management & Logistics Plan
Lifting Equipment - Crane & Fork Lift List
Make and Model SWL DNV Inspection Outstanding Actions Safety Inspection
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Comments:
Inspected by: Signature: Date:
8. Rig Move Management & Logistics Plan
Truck Safety Pre-move Inspection Procedures
Inspection Protocols OK Minor-comments Non-Serious-comments Serious-comments
1 Driver – current license and competent
2 Truck – general appearance & condition
3 Deck/bed condition
4 Retainer Pins available
5 Blocking Timbers available
6 Chain & Boomers – available & condition
7 Headlights, taillights, signal lights & horn
8 Reverse alarm installed
9 Tires for under inflation and severe cuts
10 Steps and handholds for damage
11 Cracks or broken windows
12 Fuel
13 Instructions/directions to next location known
14 Speed limit known and understood
15 Correct PPE
16
Malfunction or damage of any readily visible or
accessible component of the truck which is not
included elsewhere in the inspection
Comments:
Inspected by: Signature: Date:
9. Rig Move Management & Logistics Plan
Pre Job Safety Meeting –Truck Drivers
No. Name Company Signature
Trucks are to be parked in order - off the Drilling Location
and in the lay down area beside the Rig. All vehicles are to
be in single rows.
Drivers will conduct quick inspection of vehicle prior to - go
location and receive load.
Trucks will come on location one at a time or as instructed
by the Truck Push.
Drivers will move to clear area and secure load prior to
moving off the Drilling Location – all loads will be chained
with boomers and tie-downs.
Loads will be backed under when possible to minimize
Crane movement of loads.
With truck loaded and secured they will move off the Drilling
Location and assemble for Convoy.
Drivers will conduct quick inspection of vehicle prior leaving
with Convoy.
Concession Speed limit maximum is 60kph – Convoy speed
is 20 to 40kph maximum
Distance between Trucks at 10 meters minimum.
Escort vehicle is to be followed at all times.
Drivers will not change oil and dump on ground – all waste
oils will be disposed of in waste barrels.
There is to be no littering or throwing of garbage anywhere
in the TFE Concession.
If an unsafe situation is apparent all truck drivers are
required to stop work and report the condition all accidents
are to be reported.
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Additional Items or Comments:
Meeting Chairman Signature: Date:
10. Rig Move Management & Logistics Plan
Pre-Job Safety Meeting – Crane Operators & Forklift Driver(s)
No. Name Company Signature
Daily Safety Check completed by operator.
Correct PPE – boots, coveralls, hardhat, gloves & hardhat.
Operator aware of Safe Working Load – SWL.
Outriggers to be fully extended – at all times.
Load charts and boom angle indicators in Crane Cab.
Hand signals understood.
Emergency Stop Signal understood
Operator to obey only one rigger or signalman.
Signal man identified and known.
Never start Crane movements until signalman is in sight.
All hooks to be self-closing.
No personnel to ride on loads.
Crane operator not to move loads directly over personnel.
Avoid sharp bends in slings – set loads on blocking and
never set loads directly on slings.
Do not stand or walk under suspended loads.
Do not leave loads unattended at any time.
Use Tag Lines for all lifts.
Check the SWL of all slings, chains, wire rope before using.
Inspect all rigging equipment prior to use.
Immediately discard defective lifting equipment
Do not tie knots in sling chain, rope slings or wire rope
Do not use rope for rigging or lifting loads
At any time Crane Operators can stop or suspend work if the
situation appears unsafe.
1
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5
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Additional Items or Comments:
Meeting Chairman Signature: Date: