OGTS – MO6 Health & Safety PDF

Summary

This document is a set of training notes on basic health and safety in maintenance workshops, particularly for the oil and gas industry. It covers learning outcomes, session objectives, includes a section on manual handling, and introduces the 5S methodology for maintaining a clean and safe workspace. The document was published in 2024.

Full Transcript

BASIC HEALTH AND SAFETY IN MAINTENANCE WORKSHOPS

OGTS – M06 – 01 & 02 & 03

BY: Christine Arupo Maloba
 22 July 2024 | 2

Acknowledgement

This training material has been prepared by UPIK-HSE
and Dietsmann lecturers covering OGTS-M06: 01, 02, 03
for the Tilenga Academy in accordance with OPITO
curriculum and industry best practices.
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LEARNING OUTCOMES
Describe safe working practices for a
O1 maintenance
workshop

Create a basic risk assessment for
O2 workshop maintenance tasks

Demonstrate safe working practices in
O3 a maintenance workshop
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SESSION OBJECTIVES
P1.1 Describe safe working practices for working in a maintenance workshop

P1.2 Describe the operation of safety documentation and procedures

P1.3 Identify relevant emergency requirements for a maintenance workshop

P2.1 Identify potential hazards in a workshop environment

P2.2 Describe the associated risks and implications for people, equipment and the
environment
P2.3 Describe measures that could be taken to minimise the risks

P2.4 Carry out and record a risk assessment for a maintenance workshop

P3.1 Communicate and work effectively as part of a team for maintenance tasks
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SESSION OBJECTIVES cont’d

P3.2 Take part in a tool box talk
P3.3 Use correct manual handling techniques for maintenance tasks
P3.4 Select and use the correct personal protection equipment for maintenance tasks
P3.5 Maintain the workspace in a clean and tidy manner and dispose of waste
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Describe safe working practices for
working in a maintenance workshop
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INTRODUCTION TO MANUAL HANDLING
Definition:

Manual handling is any task where people physically move, handle
or shift materials and objects.
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Manual handling
Examples of manual handling include:

lifting boxes on or off storage racks or shelves;

pushing furniture or tools;

pulling an object into a better position

carrying a package;

sliding an object out from the floor;
 9

Types of injuries
Damage to the
spine, back
muscles and
ligaments
Amputations
Abdominal
hernia

Muscle strains
Crushed limbs and joint wear
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Manuel handling
INDICATE:

Correct method

Incorrect method
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Manual handling

Risks for your back

Short term:
acute back injury from unique event
(i.e. lifting too heavy, or in bad position)

Long term:
chronic fragility/vulnerability of column
invalidity from back pain
great impact on your personal, professional and social life
 12

Causes of injuries
Overexertion - handling a load beyond the body’s
capability.

Repetitive actions - continually repeating certain
movements or maintaining a body position for long
periods.

Poor workplace layout - encourages unsafe work
postures and unnecessary manual handling.

Incorrect technique - incorrect body positions and
movements.
 13

Reducing Manual handling

Some ways to reduce manual handling tasks are by:

planning your work area

getting help from someone to carry heavy objects;

using mechanical aids, such as hand trolleys, to move
objects

finding the best possible position
 14

Safe manual lifting
Size up the load to make sure it is not too heavy or too large.
Assess the load to check contents will not move.
Adopt a stable footing.
Bend your knees and reach down to the load.
Keep your back straight as you lower yourself.
Grip the load with both hands.
Brace your stomach and buttock muscles.
Slowly push up with your legs and keep your back straight.

Never bend at the waist, always bend at the knees - it makes the job ten times
easier on your back.
15
 16

Carrying load
When carrying a load:
keep the load close to your body;
keep the load at no more than waist to chest height; and
take short steps.

If a load is too heavy or too large for you to lift and carry on your
own, use a mechanical aid, or get someone else to assist you.
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Carrying load

To use a four-wheeled lifting aids, such as Carts
and Platform Trucks:
Push, rather than pull, the cart.
Be aware of traffic in front of you.
Allow an adequate stopping distance
At the destination, secure the cart so it won’t
roll
 18

Pushing or pulling loads
When pushing a load you should:
place your feet apart with one well behind the other;
lean forward;
gradually apply your body weight; and
push forward with your rear foot to set the load in motion.
When pulling a load you should:

place your feet apart with one well behind the other;
lay back into the line of pull;
gradually apply your body weight; and
push backward with your front foot to set the load in motion.
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The Individual, Strength

Is your strength height &
fitness appropriate to the
task?
Everyone’s different!
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The Individual, Strength
Have you been trained for
the task?

If you need training or
information, ask your
Supervisor
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The Load, Shape
Do I need someone to help me lift?

Ask for help, check the weight by
tipping it and communicate clearly
then check that everyone involved
feels comfortable carrying the load
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The Load, Hazards
Do not carry large objects that will
obstruct your view

It is important that your field of
vision is clear when lifting lowering
and carrying

Look out for sharp edges
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The Environment, Layout
Is the lighting good
Can the workplace be reorganized?
Obstructions should be cleared to
provide enough space for correct
positioning of the load
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The Environment, Ground condition
Is the floor uneven, slippery or
unstable?

Check the floor for hazards
such as, oil, steps or spillage
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The Environment, Temperature
Perspiration on hands can
reduce grip

Hand gloves should be
used to ensure better grip
 22 July 2024 | 26

Whatever you are lifting or moving:

Use appropriate
personal protective equipment

Take special precautions when handling
chemicals and hazardous materials
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WORKING AT HEIGHTS
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INTRODUCTION TO WORKING AT HEIGHT SAFELY
Working at height remains one of the biggest causes of fatalities and
major injuries during maintenance works.
Common cases include falls from ladders and through fragile surfaces.
'Work at height' means work in any place where, if there were no
precautions in place, a person could fall a distance liable to cause
personal injury (i.e. a fall through a fragile roof).

Employers can take simple, practical measures to reduce the risk of any
of their workers falling while working at height.
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Video
https://youtu.be/00f0A1ppnRo
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Scaffolding Awareness
Scaffolding is a temporary work platform used for working at heights.
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Generally, Height is defined as anything greater than 1.8m.
Any work done beyond 1.5m is work at heights (newly revised)

Falling from height remains the single greatest cause of severe injury
and or death in the construction and Refining industry.

Single most expensive cost related injury.
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Here is a simple equation for determining the
required distance:

- Lanyard Length – The length of the lanyard or
retractable device connected to the harness
anchorage point.

- Deceleration Distance – The distance between the
start of the fall to when the fall arrest system engages.
OSHA limits this distance to 3.5 feet or less.

- Work Height – The height where the work is taking
place.

- Safety Factor – Additional safety distance below the
worker.

The height and weight of the worker should also be
considered when determining fall clearance.
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https://youtu.be/qFhLaP4xZ1A
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CONFINED SPACES
CONFINED SPACES
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DEFINITION OF CONFINED SPACES
Confined space is space that:
Is large enough & so configured that employee can
bodily enter & perform assigned work
Has limited or restricted means for entry or exit (i.e.
tanks, vessels, silos, pits, vaults or hoppers)
Is not designed for continuous employee occupancy
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ISSUES OF CONFINED SPACES
The accidents related to work within a confined space are most of the time serious
accidents or fatalities

Most of these fatalities were related to a deficiency in oxygen or to a presence of toxic
gasses or flammables

60% of these victims were workers who tried to rescue without having the necessary
knowledge and equipment
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EXAMPLES OF CONFINED SPACES
For example the following locations could be confined spaces:
A reservoir, a silo, a tank, a bunker, a chamber, a dome, a pit, a
sewer, a pipe, a chimney, manhole, wagon or tanker truck, etc.
 22 July 2024 | 40

EXAMPLES OF CONFINED SPACES

Boiler tanks… Pipe chases… Crawl spaces…

Manholes… Pits...
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EMPLOYER’S RESPONSIBILITIES

The employer has the responsibility to draw up an inventory of all his
confined spaces and to do the risk assessment, by a qualified person, to
issue the safety work procedure which should be strictly followed

He has also to assure that the workers have the knowledge, an adequate
training or experience in order to perform the work safely

Moreover, he has to provide them with the appropriate work and
personal protective equipment which should be in good overall
conditions
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OXYGEN DEFICIENCY
The air normally contains 21% of oxygen.
When the concentration in oxygen is less than 19.5% in the air, it is
forbidden to enter a confined space
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THROUGH THE DISPLACEMENT OF OXYGEN
BY OTHER GASSES
Many gasses, mainly inert gases (argon, nitrogen, carbon dioxide, etc.), the
gasses used in the portable fire extinguishers, and refrigeration gasses, can
displace the oxygen
 22 July 2024 | 45

EFFECTS OF OXYGEN CONCENTRATIONS ON HUMAN BODY

✓ 23,5 %: Atmosphere rich in oxygen. Superior limit from which it is forbidden to
enter

✓ 21,0 % : Normal oxygen concentration

✓ 19,5 % : Minimum concentration to enter in a confined space without a respirator
self-rescue apparatus or with an air supply respirator

✓ 12 % to 16 %: Spasmodic breathing, anxiety, abnormal fatigue when doing some
movements, insufficient concentration to keep a flame in ignition

✓ 10 % à 11 %: Acceleration in breathing and heart rate, euphoria, headaches.

✓ 6 % à 10 %: Nauseas and vomiting, inability of moving freely, possibility of loss
of consciousness and collapse while being conscious
✓ Less than 6 %: Breathing failure followed by heart failure, death in a few minutes
 22 July 2024 | 46

OXYGEN

A. The Oxygen:

IN A NORMAL ATMOSPHERE OXYGEN CONTENT IS 21%

An atmosphere which is rich in oxygen ( 23,5% and higher),
increases material flammability levels.

It is strictly forbidden to enter a confined space containing more
than 23,5% of oxygen
 22 July 2024 | 47

OXYGEN ENRICHED ATMOSPHERES

Enriched Oxygen levels cause flammable and
combustible materials to burn violently when
ignited.

▪ Hair, clothing, materials, etc.

▪ Oil-soaked clothing and materials.

Never use pure oxygen to purge/vent equipment.

Never store or place compressed tanks in a
confined space.
 22 July 2024 | 48

TOXIC SUBSTANCES ATMOSPHERES
The deficient natural ventilation and the low air volume of many confined spaces lead
workers to be exposed to important concentrations of contaminants

A toxic atmosphere contains gasses, vapors or smoke well-known to have noxious
(harmful) effects on human body. The toxic effect is independent from the oxygen
concentration
 22 July 2024 | 49

IF POSSIBLE,TRY TO AVOID ENTERING IN CONFINED
SPACES?
The first question to ask when elaborating a Contingency Plan in confined spaces is the
following:
Could we avoid entering in confined spaces?
There are all sorts of methods allowing to achieve the same results without entering in a confined
space.
For instance, the use of cameras and Robotic equipment.
Robotics for industrial cleaning in confined spaces and Suction Excavators (youtube.com)
 22 July 2024 | 50

ROBOTICS FOR INDUSTRIAL USE
 22 July 2024 | 51

QUALIFIED PERSONS: The Attendant
Individual stationed outside one or more permit spaces who
monitors authorized entrants & performs all attendant’s duties
assigned in employer’s permit space program
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The Attendant

Duties of Attendants

◼ Know hazards that may be faced during entry

◼ Aware of possible behavioral effects of hazard exposure in authorized entrants

◼ Continuously maintain accurate count of authorized entrants

◼ Remain outside permit space during entry operations until relieved by another
attendant
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The Attendant

Duties of Attendants

◼ Communicate with authorized entrants

◼ Monitor activities inside & outside space

◼ Summon rescue & other emergency
services

◼ Perform non-entry rescues as specified
by employer's rescue procedure

◼ Perform no duties that might interfere
with primary duty to monitor & protect
authorized entrants
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The Attendant

The attendant should not enter in the confined
space to make the rescue if all the conditions
mentioned below are not respected:

He is also trained to enter in the confined
space to make the rescue.
He has the personal protective equipment
required.
He is replaced by another attendant.
 22 July 2024 | 55

AUTHORIZED ENTRANT

Duties of Authorized Entrants

❑ Know hazards that may be faced during entry, including information on mode, signs
or symptoms & consequences of exposure

❑ Properly use equipment and trained

❑ Communicate with attendant as necessary to enable attendant to monitor entrant
status & enable attendant to alert entrants of need to evacuate space
 22 July 2024 | 56

Personal protective equipment

Do not enter a confined space
without hands-on training in use of
equipment
 22 July 2024 | 57

RESPIRATORY PROTECTION
Breathing apparatus are not required when atmospheric conditions in the confined
space are compatible with the following criteria:

❑ Oxygen concentration higher than 19,5% and lower than 23,5%,
❑ Gas or flammable vapors concentration lower than 10% of the Lower
Explosive Limit (L.E.L.),
 22 July 2024 | 58

If the atmospheric conditions do not correspond to the standards previously
mentioned. The area should be considered as being hazardous or as an area
representing an immediate danger for the health and life.

A special equipment should then be used. (Robotic Equipment)

The respiratory protection choice is done by a gradual elimination of the
inappropriate respirators according to the current conditions.
 22 July 2024 | 59

Supplied Air Respirators

During Confined space rescue, conventional SCBA’s size often makes it difficult to
use
SCBA small enough to pass through narrow openings may limit duration of its air
supply to impractical levels
 22 July 2024 | 60

I MUST
Ensure a safety watcher is present and
communication devices are working
The safety watcher continuously monitors the in/out movement during the task
The safety watcher communicates with the workers in the confined space
In the case of an emergency, the safety watcher calls the rescue team
Read and understand the emergency plan
Everyone involved in a confined space task must know precisely
what to do in an emergency
Emergency and rescue devices should be available whenever
work is carried out in a confined space
 22 July 2024 | 61

I MUST NOT
Enter a confined space without
authorization / confined space permit
No authorization / permit = No entry to a confined space
Confined space intervention = Special permit

Work in a confined space on my own
The worker and the watcher must be in
constant permanent contact
 22 July 2024 | 62

SAFE PRACTICES

Working inside a tank
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 22 July 2024 | 64

Safety isolation procedures
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Introduction
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Isolation
When working on an electrical
installation, maintenance, inspection,
it’s vital that you disconnect the
equipment from the live supply and test
whether any current is running through
it before making a start on the task at
hand. In the electrical trade, this
process is referred to as safe isolation.
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Once you’ve disconnected an installation from the rest
of the circuit and checked that no current is flowing
through it, the system is said to be “dead” (as opposed
to “live”).
At this point, you can safely start investigating and fixing
the installation.
We isolate systems from the rest of the circuit prior to
working on them primarily for safety purposes: if part of
the installation is still live (i.e. connected to the mains
supply), then you and other people on site run the risk
of receiving an electric shock and serious burns
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Energy Sources
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Lockout /Tagout (LO/TO)
Lockout:
Use to hold an energy isolating device in the safe position
and prevents the energizing of an equipment.
Tagout:
Use along with lockout devices as an additional warning or
information.
This tag can only be removed by the person originally
installing it or a qualified electrician.
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Therefore, Lockout/Tag-out refers to a safety procedure
which is used in industry settings to ensure that dangerous
machines are properly shut off and not started up again
prior to the completion of maintenance or servicing work.
It protects the employees from the unexpected
energization or release of hazardous energy during service
or maintenance activities
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Lockout devices

Lock with one key and tag
Chains
Flanges
Pipe blank or bling
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Tag out devices
Tags are always attached to the lock or energy
isolation devices
Serves as a communication device
TAG STAGES: DONOT OPERATE and securely
fastened.
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The process of tagging out a system involves attaching information
tag or indicator (usually a standardized label) that includes the
following information:
Why the lockout/tag out is required (repair, maintenance, etc.).
Time and date of application of the lock/tag.
The name of the authorized person who attached the tag and lock
to the system.
Note: ONLY the authorized individual who placed the lock and tag
onto the system is the one who is permitted to remove them.
This procedure helps make sure the system cannot be started up
without the authorized individual's knowledge.
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Isolation procedure
Preparation
Equipment shout down
Equipment isolation
Application of LO/TO device
Release the stored energy
Verification
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Isolation procedure cont’d
An isolation procedure is a set of predetermined steps
that should be followed when workers are required to
perform tasks such as inspection, maintenance, cleaning,
repair and construction.
Before any task is preformed at the plant, it must be shut
down and its energy sources locked out and tagged as
part of the Isolation procedure to ensure the safety of
those doing the work. Example of energy sources that
need to be locked out and tagged are; electricity,
hydraulic pressure, compressed air or gas, kinetic spring
tension and moving parts.
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Isolation procedure
Preparation
Identify and isolate hazardous energy sources and
understand how to use the equipment
Equipment shout down
Stop buttons and follow shut down procedure of the
equipment properly.
Equipment isolation
Install devices to isolate hazardous energy sources
 24 June 2019 / ‹#›

Apply Locks and Tags
If something can be locked, it MUST be locked, if it
cant be locked then it MUST be tagged
Release the stored energy
Guard against the residual energy
Verification
Try activating start button to ensure everything is off,
check interlock, and be sure area is clear. No
response means isolation is verified. Return controls
to the safe position (off).
 24 June 2019 / ‹#›

Generally;
Shut down the machinery and equipment
Identify all energy sources and other hazards
Identify all isolation points
Isolate all energy sources ( in the case of electrical
equipment , whole current isolation, such as the main
isolator should be used instead of control isolation by
the way of the stop button on a control panel)
Control or de-energise all stored energy
Lock-out all isolation points using multi-padlock hasps
and danger tags
Danger tag machinery controls, energy sources and
other hazards
 24 June 2019 / ‹#›

Importance of the lockout procedure

To Isolate all forms of potentially hazardous energy
to ensure that accidental release of hazardous
energy does not occur.
To Control all other hazards to those doing the work
To Ensure that entry to a restricted area is tightly
controlled
To ensure safety for all.
 24 June 2019 / ‹#›

Different locks/tags used in tagout
procedure
Yellow = Affected worker places his yellow (if he is
not the person who locked out the simple
equipment) lock on the Multilock hasp (1 or 2 lock
points) or the lockbox (Multiple lockout points)prior
to working on the equipment.
 24 June 2019 / ‹#›

Red= Authorised worker locks out the equipment with the
red locks in combination with an isolation tag attached to
each lock and also attaches the red lock and personal
danger tag which personalizes the lock to secure the
lockbox. For simple lockouts the trained affected
worker also uses the red lock in combination with their
Personal danger tag to lock out the equipment.
 24 June 2019 / ‹#›

Purple = When a lock out crosses over a shift a transition
purple lock is placed on the lockbox by the authorised
worker. He then removes his own red lock and PDT. He
hands the key of the purple lock over to the next
authorised worker coming on or places the key in a
designated secure location in the workshop. The next
authorised worker coming on then checks the machine and
place a red lock with his PDT on the lockbox when he is
satisfied that the equipment has been locked out correctly
and then removes the purple lock.
 24 June 2019 / ‹#›

Orange = A contractor working as an Affected
worker places his orange lock on the Multilock hasp (1 or
2 lock points) or the lockbox (Multiple lockout points)
prior to working on the equipment. It is the responsibility
of the need manager/designate to ensure that the
contractor puts his lock & isolation tag on the lockbox or
multilock hasp.
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Keyed Alike padlocks= In some case these locks
are keyed alike in that one key opens numerous
locks however this key is unique to these set of
locks. These are used in complex lockouts where
numerous sources of energy need to be locked
out at any one time.
 24 June 2019 / ‹#›

Caddy = A caddy is used to carry locks to their
destination. It is especially useful for keyed alike locks
where (X) amount of locks are required to lock out a
specific machine. There is only (X) amount of holes
punched in the caddy to reflect the amount of locks
required for that lock out. The one key used to open
these locks is attached to the caddy. A Caddy can carry
up to a maximum of 12 locks.
 24 June 2019 / ‹#›

Tags
Personal Danger Tags (PDT)
Each authorised and affected worker must be issued
with at least one PDT. Most will be issued with 4-5
depending on their area and job.
A PDT is a personally issued tag, with information
about the owner which personalizes the lock it is
attached to. It also has on the rear of the tag the 12
step process which must be followed each time a lock
out occurs. Each PDT is unique and will clearly identify
the owner of that tag.
 24 June 2019 / ‹#›

The PDT in combination with a red lock (Authorised
Worker) which is applied to the lockbox or multilock
hasp indicates that this person has locked out the
machine.
The PDT in combination with a yellow lock (Affected
Worker) which is applied to the lockbox or multilock
hasp indicates that this person is working on the
machine.
The PDT in combination with an orange lock
(contractor) which is applied to the lockbox or
multilock hasp indicates that this person is working on
the machine.
 24 June 2019 / ‹#›

Isolation Tag
An Isolation tag is applied to each lock-out point of the
equipment accompanied by a red lock, to indicate that
isolation point has been isolated and is not operational.
The isolation tags are only used when a lock box is used.
The PDT is applied directly to the isolation points where
there are 2 or less isolation points.
An isolation tag is also attached to the transition lock by
the authorised worker when attaching the lock to the
lockbox detailing the time and date the transition lock was
applied and by whom and also from which shift it is being
transitioned to and from.
Periodic contractors who have not been issued with a PDT
will use an isolation tag recording their name, date, their
contact # and their company and attach it to the orange
lock which they have attached to the lockbox.
 24 June 2019 / ‹#›

Lock-Out Box
A lock-out box is used to store keys to multiple
equipment locks, used when a machine has multiple
energy sources. The lock-out box is then locked with the
lock and PDT of each person who will work on the
machine regardless of the work being carried out.
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Multi-padlock Hasp
A Multi-Padlock Hasp is used so that a number of workers
may apply their locks and personal danger tags (PDT) to
the isolation points of a simple machine. This is usually
used in combination with a red lock & PDT when there are
2 or less isolation points on the equipment. If another
person is working on the equipment he/she will place a
yellow lock and PDT on each hasp or in the case of a
contractor an orange lock & PDT/isolation tag.
 24 June 2019 / ‹#›

https://youtu.be/CV6BDf40yZg
 24 June 2019 / ‹#›

Use of Machine Guards

Machine guards are protective devices that cover moving
pieces of machinery that may pose a danger to workers.
Moving machine parts present a hazard to machine operators
and flying debris can affect anyone in the vicinity of a machine
As a result, industrial machines are required by law to have
guards that protect workers from the risk of injury while they
are at work.
 24 June 2019 / ‹#›

Use of Machine Guards

If at any time, the guard has to be removed in order for
maintenance to take place, all systems should be completely
powered down to ensure that injuries cannot take place while the
guard is not in position.
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Key points about machine guards

Purpose: The fundamental purpose of
machine guarding is to reduce the risk of
injury to the machine operator or
workers. Guards prevent access to areas
that may cause harm, such as pinch
points, shear points and points of
operation
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Types of barriers
Fixed Barriers: These are physical barriers that prevent direct
contact with hazardous areas. They can be permanently fixed or
removable.
Presence-Sensing Devices: These automatically stop the machine
when a person enters a danger zone.
Automated Feeding and Ejection Mechanisms: These eliminate
operator exposure to the point of operation while handling
materials.
Machine Location or Distance: This method removes the hazard
from the operator’s work area
Best practice
Always use machine guards when operating or
maintaining equipment.
Ensure proper guard installation and check that
they are secure.
Regularly inspect guards for any damage or wear.
Train employees on the importance of machine
guarding and safe equipment operation with
guards in place
7/22/2024
Safe work practices for a
maintenance workshop
Safe work practices are generally written
methods outlining how to perform a task
with minimum risk to people,
equipment, materials, environment, and
processes.
Safe work practices should be developed
as a result of completing a job safety
analysis (JSA) or a hazard risk
assessment (HRA) and should closely
reflect the activities most common in
the company's type or sector of
construction.
 All safe work practices should be kept in a location
central to the work being performed and readily
available to the workforce.
Some safe work practices will require specific job
procedures, which clearly set out in a chronological
order each step in a process as usually specified in
the JSA.
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Safe work procedures are usually developed by
management and workers as a result of a JSA/HRA,
accident or incident investigation, and/or as a
supplement to a safe work practice.
Safe work procedures should be included in the
company's "Worker Orientation" program.
All workers should be aware of the fact that safe work
procedures have been established, are in effect, are
written down, and must be followed.
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Determine the overall task that requires a safe work
procedure.
Break down the task into its basic steps.
Identify the hazards associated with each step, and
ways to eliminate or minimize the risks to workers from
these hazards.
Write the safe work procedure, for example the list of
actions that workers must do when performing the task.
Example: fixing a blown bulb
 24 June 2019 / ‹#›

Basic steps Hazards Risk control measures

Isolating the workplace Electrical shocks Wear appropriate PPE, follow the
from any Work place safety procedures
power(electricity)

Removing the blown Trips and falls Use scaffoldings
bulb and replacing it Appropriate PPE
with a working bulb
 24 June 2019 / ‹#›

Safe work procedures are directions on how work is to
be carried out safely and are required for all hazardous
tasks performed at your workplace. They identify
hazards and clarify what must be done (precautions) to
eliminate or minimize risks.
(Series of specific steps that guide a worker through a
task from start to finish in a chronological order. Safe
work procedures are designed to reduce the risk by
minimizing potential exposure.)
Hydrogen sulfide
How Is Hydrogen Sulfide Formed?

Hydrogen sulfide is formed when organic matter
decays
It is also generated as a common by product of
industrial manufacturing processes
It is formed under low oxygen conditions when
sufficient amounts of sulfur and bacteria are
present. It can be present places such as
Oil and gas reservoirs, sewers and sewage
processing facilities ,swamps, dark and damp places
where bacteria is present
7/22/2024
 Objectives:
Introduce safety practices
related to H2S
Discuss methods of
detection for H2S

7/22/2024
General safety
Even though H2S has very
strong odor, it’s warning
properties are poor.
Often times, employees think
that just because they can’t smell
H2S that it’s not present.
If odor is detected, leave area
until source is identified,
controlled, and area made safe.

7/22/2024
7/22/2024
General safety cont’d

If you don’t have proper
respiratory protection,
STAY OUT!
Use warning signs to
alert personnel.
Use fencing to keep
unauthorized personnel
out.
7/22/2024
General safety –wind direction
indicators

Post wind direction indicators
in areas where H2S is present
or has potential to be present.
Wind direction indicators give
visual cue as to presence and
direction of wind.

7/22/2024
 Use wind direction
indicators, such as…
Windsocks
Flags
Banners
Streamers

Use H2S monitors and
detectors
7/22/2024
General safety signs

Signs to indicate the
potential for or the
presence of H2S
Signs to prohibit smoking
Signs to prohibit ignition
sources
Other signs as needed

7/22/2024
 General Safety -Fences

Fence off dangerous areas,
including:
Tanks,
Open pits,
Wellheads

Install fences far enough away
Post signs on fences

7/22/2024
Monitoring equipment
Two basic types of monitoring equipment:
Fixed

Portable

7/22/2024
7/22/2024
Fixed monitoring equipment

Used in permanent locations
Can detect single or multiple gases
Have reset alarm level
Have audio and visual alarms

7/22/2024
7/22/2024
Portable monitoring equipment

Two basic types of portable monitoring
equipment:
Electronic
Non-electronic

7/22/2024
Portable electronic monitors

Can be single gas or multi-gas
Usually handheld, clipped to
belt, or carried in shirt pocket
(should be in the breathing
zone)
Some have LCD
Some alarm only

7/22/2024
Portable electronic

Diffusion type monitors
have a sensor that allows
gas to enter, then uses
microprocessor to
determine the
amount of gas present
7/22/2024
7/22/2024
Portable electronic monitor

‘BW Clip4’ app

7/22/2024
Portable electronic-advantages

Accurate
Light weight
“Go anywhere”
Easy to Use
Low Cost

7/22/2024
Portable electronic -disadvantages

Monitors must be calibrated
and tested

Must order calibration gas

Sensors expire

Calibration gas expires

Sensors can be “overloaded”

7/22/2024
Portable non-electronic
Pump draws known amount of air
through tube filled with reagent
Reagent changes color
Amount of color determines
amount of gas present

7/22/2024
Portable non -electronic- advantages
Relatively low cost
No batteries
Easy to use

7/22/2024
Portable non-electronic-advantages
Accuracy is about + 25%
Pumps can leak
H2S can corrode the pump
Have broken glass tubes

7/22/2024
Portable non-electronic -
disadvantages

Tubes expire

Cannot mix pumps and tubes
from different manufactures

Colors may be hard to read

7/22/2024
 https://youtu.be/ZkoKCvL_jwU
https://youtu.be/5P-PoIUE6LI

7/22/2024
7/22/2024
 24 June 2019 / ‹#›

CONTROL OF SPILLAGES, USE OF SPILL KITS
 24 June 2019 / ‹#›

CHEMICAL SPILL KIT

You can clean up minor chemical spills where there are no injuries, that do not pose any
threat of a fire and for which you have the proper training and proper protective
equipment.
Chemical spill clean-up kits are helpful to have in the laboratory and other service areas
which use chemicals. The kits are useful if you and your fellow workers know how to
use them properly. Chemical absorbent pads or socks or neutralising powder can be
used to quickly contain a spill.

Use these items only if you are not in any danger. Often the best use of such a kit is to
put the absorbent on the spill to contain the chemicals, then leave the room and secure
the area until the proper authorities arrive to finish the clean-up.

Emergency spill kit
 24 June 2019 / ‹#›

Is this an emergency? If you can clear up the leak on the spot it should not be
regarded as an emergency. If you are not sure, consider it an emergency. The
following are examples of spills and leaks that should be considered emergencies:
Type of spill Amount Examples

extremely flammable liquids 500 ml propylene oxide

flammable liquids 750 ml toluene

combustible liquids 750 ml mineral spirits

toxic, volatile liquids 750 ml ammonia

concentrated acids 4.5 litre sulphuric acid

concentrated alkalis 4.5 litre lye solution

poisonous, reactive materials Any amount cyanides, sulphides

oxidising agents 500 mg concentrated nitric acid

leaks from gas cylinders uncontrolled oxygen, acetylene

Table 1: Examples of spills and leaks that should be considered emergencies
 24 June 2019 / ‹#›

FIRST RESPONSE TO A CHEMICAL SPILL
Move away from the immediate area: The first person to notice the spill or leak
should move away from the immediate area of the spill in order to evaluate the
situation without breathing in any fumes from the chemical. Check the wind
direction to ensure that you move downwind of the spill. This may not be necessary
if it is a small spill of a harmless chemical.

Try to identify the spill: Do so without placing yourself at risk. This includes
identifying:

▪ the type of material spilled (e.g., from the label);
▪ the size of the spill and whether the leak has stopped;
▪ whether two chemicals are involved in the leak and could react with each other;
▪ any unusual features such as foaming, odour, fire, etc.
 24 June 2019 / ‹#›

PROCEDURES TO HANDLE MINOR CHEMICAL SPILLS

Tell everyone in the immediate area about the spill.

Avoid breathing in vapours/fumes from spill.

Put on protective equipment, including safety goggles, suitable gloves, and long-
sleeved laboratory coat/overall.

Confine spill to small area, i.e. stop it from spreading.

Use appropriate materials to neutralise and absorb inorganic acids and bases.

Clear up the chemical waste material, place in the appropriate container, and
dispose as chemical waste.

For other chemicals, absorb spill with vermiculite, dry sand, or absorbent pads.

Clean spill area with water.
 24 June 2019 / ‹#›

PROCEDURES TO HANDLE MAJOR CHEMICAL SPILLS

Attend to injured or contaminated persons and remove them from exposure.
Alert people in the area to evacuate.
If spilled material is flammable, turn off ignition and heat sources.
Close doors to affected area.
Call the emergency controller.
Be prepared to tell the emergency controller the following:
Your name and department/workplace

What chemical(s) are involved

How much was spilled

Where the spill is located.
 24 June 2019 / ‹#›

CONTINUED

Nature of any injuries

What control measures have been taken

Wait for spill clean-up personnel to arrive
24 June 2019 / ‹#›
 24 June 2019 / ‹#›

NOISE AWARENESS
 24 June 2019 / ‹#›

Noise Exposure At Work

Contents:
The effects of noise on hearing,
Hearing protection – purpose, types and use,
Purpose of Noise monitoring and how it’s done.
 24 June 2019 / ‹#›

What Exposure to Loud Noise Will Do

Exposure to loud noise will inevitably cause hearing loss
over time.

Loud noise damages or destroys the nerves in the inner
ear.

Another effect can be “tinnitus” or permanent ringing in the
ear.
 24 June 2019 / ‹#›

EFFECTS OF NOISE EXPOSURE
When is Noise Too Loud?
Noise is measured in units called “decibels” or “dBA”
If two people 1 Meter apart must shout to be heard, the background noise is too
loud (above 85 decibels).

Noise above 140 decibels causes
pain and immediate hearing loss.
 24 June 2019 / ‹#›

Effects of Noise Exposure
Our ears can recover from short exposure to loud noise, but over time nerve damage
will occur.

The longer and louder the noise, the greater chance permanent damage will occur.

There is really no such thing as “tough ears” or “getting used to it”.
 24 June 2019 / ‹#›

Effects of Noise Exposure
Hearing loss from noise exposure is usually not noticed because it is so gradual.

Usually a person loses the ability to hear higher pitches first.

Often the first noticeable effect is difficulty in hearing speech.

Scientific studies have shown that hearing loss can occur
when 8-hour average noise exposure exceeds 85 decibels.
 24 June 2019 / ‹#›

Effects of Noise Exposure
The table below shows noise levels and how long a person can be exposed without
hearing protection before there is damage to the ear.
Noise Level Allowable Exposure Time

80 decibels 8 hours
90 decibels 4 hours
100 decibels 1 hour
105 decibels 30 minutes
110 decibels 15 minutes
115 decibels 0 minutes
 24 June 2019 / ‹#›

Noise Levels
Examples of Commonly Used Noisy Equipment

Equipment Noise Level
Back Hoe 85-95 decibels
Chain Saw 110 decibels
Front-end Loader 90-95 decibels
Gunshot 140 decibels
Jackhammer 112 decibels
Lawn Mower 90 decibels
Tractor 95-105 decibels
Circular Saw 90-100 decibels
 24 June 2019 / ‹#›

Hearing Protection
TYPES OF HEARING PROTECTION
There are three types of hearing protection – ear
muffs, earplugs and ear caps.

Ear muffs and earplugs provide about equal
protection, ear caps which are less common
provide somewhat less protection.
 24 June 2019 / ‹#›

Hearing Protection – Ear Plugs
Earplugs are made of foam, rubber or plastic and are
either one-size-fits-all or in sizes small, medium and
large.

Some are disposable, some are reusable.

They are lightweight, and require no maintenance.

They are inserted into the ear canal.
 24 June 2019 / ‹#›

INSERTING FOAM EARPLUGS

Earplug incorrectly inserted Earplug correctly inserted
 24 June 2019 / ‹#›

EAR MUFFS

Ear muffs cover the whole ear and are preferred
by some people.

They have replaceable pads and some high-tech
styles filter out specific noise pitches.

They last longer than most plugs.
 24 June 2019 / ‹#›

Hearing Protection

How can you hear anything with earmuffs on?

Using earmuffs or plugs in noisy areas
actually makes it easier to hear coworkers or
machinery.
They reduce overwhelming loud background
noise.
They are similar to dark glasses that reduce
the sun’s glare making it easier to see.
SOME FINAL WORDS 24 June 2019 / ‹#›

▪ Noise can cause serious permanent
damage.

▪ This Damage is easy to avoid – use your
PPE – and common sense!

▪ If you think you are being exposed to
excessive noise – speak to your Supervisor
or to your HSE Officer.
 24 June 2019 / ‹#›

P1.2

Describe the operation of safety documentation and procedures
Safety documentation and
procedures
Safety documentation and procedures are crucial
for maintain workplace safety and regulatory
compliance, the following are some of the
documentation and procedures every workplace
must have.
Policies and Procedures: These outline safety rules,
expectations, and protocols within the
organization.
 Standard Operating Procedures (SOPs): Detailed
instructions on how to safely use hazardous
equipment and perform specific tasks.
Emergency Evacuation Plans: Clear guidelines for
evacuating the workplace during emergencies.
Risk Assessments: Assessments of potential
hazards and risks in the workplace.
Safety Data Sheets (SDS): Information about
hazardous chemicals and substances
 Training Records: Documentation of safety training
provided to employees.
Incident Reports: Records of accidents, near
misses, or injuries.
Safety Inspections and Audits: Regular checks to
identify safety issues.
First Aid Procedures: Guidelines for providing first
aid in emergencies.
 Lockout/Tagout (LOTO): Procedures to safely isolate
and de-energize machinery or equipment during
maintenance or repair.
Confined Space Entry: Guidelines for working safely in
confined spaces, including proper ventilation,
communication, and rescue procedures.
Fall Protection: Procedures for preventing falls from
heights, including the use of harnesses, guardrails, and
safety nets.
Personal Protective Equipment (PPE): Guidelines on
using and maintaining PPE such as helmets, gloves,
goggles, and masks..
 Fire Safety: Evacuation procedures, fire
extinguishers usage, and emergency response
plans.
Chemical Handling and Storage: Proper
procedures for handling, storing, and disposing of
hazardous chemicals.
Electrical Safety: Protocols for working with
electrical equipment, grounding, and avoiding
electrical hazards.
 Machine Guarding: Ensuring machinery has
appropriate guards to prevent accidental contact
with moving parts.
Emergency Response: Procedures for handling
medical emergencies, spills, or other critical
incidents
P1.3
Identify relevant emergency requirements for a
maintenance workshop
Emergency requirements for a
maintenance workshop
Minimum Light Levels: Adequate lighting is crucial
for safety. Proper illumination helps prevent
accidents and allows workers to navigate the
workshop effectively.
Ventilation: Proper ventilation helps maintain air
quality, especially when dealing with chemicals,
fumes, or exhaust. Good ventilation reduces health
risks and ensures a safer environment.
 Ventilation: Proper ventilation helps maintain air
quality, especially when dealing with chemicals,
fumes, or exhaust. Good ventilation reduces health
risks and ensures a safer environment.
Disabled Access: Design the workshop to
accommodate individuals with disabilities.
Accessible ramps, doorways, and facilities are
essential for inclusivity and safety.
 Space Requirements: Consider the number of
occupants in the workshop. Ensure sufficient space
for safe movement, equipment storage, and
emergency response
Remember, prioritizing safety in a maintenance
workshop is essential for protecting workers and
preventing accidents
Who to contact in an emergency
Main contents of a typical emergency response plan
Emergency contacts
Relevant strategy and procedures for response ie. Plant
isolation
Special procedures for dealing with particular circumstances
Availability of resources /need for specialized equipment
Details of offsite assistance available
Emergency control center and locations of alternatives
Training requirements for emergency planners
Assembly point and alternatives
How to review the plan and take care of new changes
 Operations risk evaluation
Incident command structure and emergency response team
members, their roles and obligations and their training
requirements
Details of alarm systems
When to declare an emergency
Internal notification protocols
Identification of emergency responders
Standard list of information required from the site of the
incident
Information to be released to the media
Evacuation and abandonment procedures
Critical factors considered for the successful
response and evacuation of workers in an emergency
Sufficient number of escape routes
Presence of alternative means of escape in opposite
directions from most situations
Sufficient width of escape routes to accommodate the
number of people, stretchers
Reasonable travel distances between fire-resistant
compartments
Protection from the effects of fire, explosion and ingress of
smoke
Provision for manual call points to raise the alarm
 Provisions for firefighting equipment to aid escape
Adequate lighting
Provision of manual call points to raise the alarm
Suitably located escape routes to enable persons to escape to
safety
Reasonable travel distances between fire resistant compartments
Relevant signage in place
Escape routes kept free from obstructions
Availability of escape breathing apparatus
Nonuse of elevators unless they are fire resistant
Escape doors opening in the direction of travel where possible and
never locked
 24 June 2019 / ‹#›

OGTS – M06 - 01

DESCRIBE THE PURPOSE OF SAFETY
PROCEDURES/ DOCUMENTATION
 24 June 2019 / ‹#›

OGTS –M06 - 01
LEARNING OUTCOME
Permit to work systems

O1
 24 June 2019 / ‹#›

SESSION OBJECTIVES

P2.1 Describe the purpose and types of permit to work systems

P2.2 Describe the purpose of risk assessments
 24 June 2019 / ‹#›

Work - Permits
24 June 2019 / ‹#›
24 June 2019 / ‹#›
 24 June 2019 / ‹#›

PURPOSE OF PERMIT TO WORK
This document and procedure emphasis on the PTW (Permit to Work) process as it
should be applied within Total Energies. Therefore, the objective of this procedure is to:
Ensure all the PTW phases are respected and correctly followed by all personnel
involved;
Define the roles and responsibilities in this process;
Identify hazards linked to the work and evaluate the risk along the permit to work
process;
Ensure that precautions are recommended, implemented and maintained up to the
end of the work;
Coordinate the works, to avoid conflict of access or interferences of activities;
Define the maximum validity period and the required complementary certificates for a
permit to work.
 24 June 2019 / ‹#›

FIELD OF APPLICATION

The provisions of this procedure apply to all TE´s sites, activities and operations.
This procedure has to be transposed in a dedicated site instruction to provide methods
for permit to works specific to certain contexts: work on sites without industrial
operations (e.g. offices, living facilities, Logistic base…).

In case of coexistence with a work permit between TE and a contractor (for example,
supply vessel, barge and drilling platform), a "Bridging Document" is prepared to define
the application areas of each system, and thus managing the interfaces between both
parties, throughout the duration of the work.
Notwithstanding the above indications, the Responsible for Safety and Environment on
Site (RSES) Site Health, Safety Environment Manager. may decide at his sole
discretion to cover any work by a PTW, if the RSES feels necessary to better control the
risk of such work.
 24 June 2019 / ‹#›

Types of permit to work
Depending on the type and complexity of the work, the work may be performed using
one of the following forms:
▪ Standard Permit to work form;
▪ Routine permit form; (or simplified PTW);
▪ Or work that is authorized without PTW but via a Verbal instruction. Permit to work
validity period.
When the validity period of a PTW has expired, the work concerned cannot begin or be
continued without a new permit to work
A permit to work for cold work or hot work without naked flame shall expire 14 days after
the opening date (within 24 hours after approval date) and may be reduced at RSES
discretion.
 24 June 2019 / ‹#›

COLD PERMIT TO WORK
The cold permit to work provisions apply by default to all types of works other than those
covered by a more specific form and jobs not involving a naked flame, potential source
of ignition (sparks etc.).
 24 June 2019 / ‹#›

HOT PERMIT TO WORK (A AND B)
The Hot permit to work provisions apply when work involves actual or potential sources
of ignition, namely:
Jobs involving Naked flame spark or heat-producing sources (flame cutting,
welding, grinding), unless used inside workshops or areas specifically designed for
that purpose and not located in the vicinity of any hazardous area. The respective
Hot permit is then rated as “Naked Flame” (Hot Permit to work A);

Jobs involving “Non naked flame” Covers Other potential sources of ignition (hand
tools, equipment not or no more intrinsically safe), located or used inside or nearby
a hazardous area, and that cannot be isolated. The respective Hot permit is then
rated as “Non naked flame” (Hot Permit to work B).
 24 June 2019 / ‹#›

ROUTINE PERMIT
A simplified Permit to work, is used only for recurrent and low risk work that does not
generate any co-activity or simultaneous operations.
The routine permit shall be used:
▪ For regular or routine operating activities (carried out several times a year);
▪ For a duration of at least 7 days;
▪ To supported by approved procedures and routine job forms;
▪ Carried out by employees or contracted staff who are adequately trained and
experienced, and are part of the permanent organization in place at the location
(core team);
▪ Their risk assessment clearly shows that they do not involve unusual hazards or
high rated risks;
▪ Supported by an approved Job Risk Assessment, as per procedure.
 24 June 2019 / ‹#›

WORK ON VERBAL INSTRUCTIONS : The min requirements for verbal authorization’re:
▪ Activities which are part of the regular operation of the installation and its equipment,
in line with the design specifications and within the operating limits prescribed by the
manufacturers;
▪ They are supported by suitable plans / schedules, procedures, instructions,
checklists, and operating manuals;
▪ They are included on the list of the types of activities that may be carried out on
verbal / written instructions.
▪ Inhibition / overriding of safety systems are not required to perform the activity;
▪ Activity is relatively simple to perform.
NB: Any activity requiring isolation
▪ Activity is re-occurring on a regular base; cannot be executed under verbal
instruction.
▪ Activities shall be performed by regular crew only;
▪ No electrical, process/mechanical or personal isolations required.
 24 June 2019 / ‹#›

COMPLEMENTARY PERMITS

Specific operations require the use of complementary permits or specific authorizations
in addition to any permit to work. Such as, but not limited to:

▪ Confined space entry permit;
▪ Electrical isolation sheet;
▪ Process / mechanical isolation;
▪ Critical lifts plans;
▪ Safety inhibit / override permit;
▪ In case of Simultaneous Operations, the permit to work ting system may be adapted as part
of the SIMOPS dossier.
 24 June 2019 / ‹#›

P2-1 TO P2-4
HAZARD IDENTIFICATION &RISK ASSESSMENT
 24 June 2019 / ‹#›

HAZARD IDENTIFICATION RISK ASSESSMENTS

Risk assessment in the context of a maintenance workshop involves
identifying hazards, evaluating, and controlling potential hazards that
could lead to accidents, injuries, or damage during maintenance
activities.
The goal is to ensure the safety and health of workers, as well as to
protect equipment and the environment.
 24 June 2019 / ‹#›

PURPOSE OF RISK ASSESSMENTS
To provide, by means of a consistent and systematic approach, a method
to:
- identify potential hazards,
- Evaluate the potential Risk for personnel, the environment and the
asset.
- determine appropriate and sufficient control measures to reduce risks to
an ALARP level,
- develop an action plan to implement the compensatory measures.
 24 June 2019 / ‹#›

FIELD OF APPLICATION
General case
The provisions of this procedure are applicable to all sites and operations under the
control of the Company
(except otherwise stated in a specific instruction).
They apply to jobs, which are considered to be safety critical in terms of risks that they
may cause:
- personnel injury,
- environmental damages,
- impact on safety critical element,
- asset, material or production losses,
24 June 2019 / ‹#›
 Identify Hazards:
Examine all activities, tools, equipment, and materials
used in the workshop.
Look for potential sources of harm such as moving
machinery, electrical hazards, chemical exposure,
ergonomic risks, and manual handling tasks.
Assess Risks:
Evaluate the likelihood and severity of harm from the
identified hazards.
Consider factors such as the frequency of exposure,
number of workers exposed, and the potential
consequences of an incident.
Monitor and Review:
Regularly check the effectiveness of control measures.
Review and update the risk assessment periodically or
when there are changes in the workshop activities,
equipment, or after an incident.
Documentation:
Keep detailed records of the risk assessment process,
findings, and actions taken.
Ensure documentation is accessible to all relevant
personnel.
Determine Control Measures:
Identify appropriate measures to eliminate or reduce the
risks to an acceptable level.
Control measures can include engineering controls (e.g.,
machine guards, ventilation), administrative controls
(e.g., training, procedures), and personal protective
equipment (PPE).
Implement Control Measures:
Put the identified control measures into practice.
Ensure all workers are trained and understand the new
procedures and controls.
 24 June 2019 / ‹#›

P2.1 identify potential hazards in workplace
environment
 24 June 2019 / ‹#›

Hazard identification defined
Hazard identification is the process of identifying potential hazards in the
workplace that can cause harm to people, property, or the environment.
This process involves recognizing situations or conditions that have the
potential to cause injury and taking steps to prevent accidents or harm.
Hazard identification is a critical step in the risk management process and is
essential for creating a safe and healthy work environment.
It involves identifying hazards associated with tasks, equipment, or the work
environment, and then taking measures to control or eliminate these hazards to
ensure the safety and well-being of employees.
 24 June 2019 / ‹#›

Methods of Hazard identification
1. Workplace Inspections: Regular inspections of the workplace can help
identify any potential hazards or unsafe conditions.
2. Incident and Accident Investigation: Reviewing past incidents and accidents
can help identify underlying hazards and prevent future occurrences.
3. Job Safety Analysis (JSA): Analyzing each step of a job to identify potential
hazards and determine the best way to perform the task safely.
4. Safety Data Sheets (SDS): Reviewing SDS for chemicals and hazardous
materials to understand their potential hazards and safe handling procedures.
5. Employee Reports: Encouraging employees to report any potential hazards
they encounter in the workplace.
 24 June 2019 / ‹#›

Maintenance Hazards
Maintenance hazards can include electrical hazards, such as working
with live wires or faulty equipment, which can cause electrical shock or
fires.
Other hazards may include working at heights, handling heavy
machinery and equipment, exposure to chemicals, and potential for slips,
trips, and falls in the maintenance area/workshop.
It's essential to identify and mitigate these hazards to ensure the safety of
maintenance workers and those in the surrounding area.
 Common Hazards in Maintenance Workshops
Mechanical Hazards: Moving parts of machinery can cause injuries such as cuts,
entanglement, and crushing.
Electrical Hazards: Working with or near electrical equipment can lead to electric
shock or burns.
Chemical Hazards: Exposure to hazardous substances (e.g., solvents, lubricants)
can cause health issues.
Ergonomic Hazards: Poorly designed workstations or repetitive tasks can lead to
musculoskeletal disorders.
Noise and Vibration: High levels of noise and vibration from tools and machinery
can affect hearing and health.
Fire and Explosion Hazards: Flammable materials and processes can pose fire
risks
Poor House keeping: cluttered materials, cables, tools
P2.2 Describe the associated risk and implication for
people equipment and environment.
Risk and implication for people equipment and
environment.
1. Mechanical Hazards
Risks:
Entanglement in moving parts. Implications for
Equipment:
Cuts or amputations from sharp edges or
Damage to machinery.
tools.
Increased maintenance
Crushing injuries from heavy machinery costs.
or equipment Implications for the
Implications for People: Environment:
Serious injuries or fatalities. Potential oil or hydraulic
fluid leaks from damaged
Permanent disability. equipment
2.Electrical Hazards
Risks:
Electric shock or electrocution from exposed wires or faulty
equipment.
Electrical fires.
Implications for People:
Burns, cardiac arrest, or death.
Implications for Equipment:
Fire damage to electrical equipment.
Downtime due to equipment failure.
Implications for the Environment:
Fire spreading to nearby areas, causing broader environmental
damage.
3. Chemical Hazards
Risks:
Exposure to hazardous substances such as solvents, lubricants, or
cleaning agents.
Chemical burns or respiratory issues from inhalation.
Implications for People:
Acute health effects such as skin irritation or respiratory problems.
Chronic health conditions from long-term exposure.
Implications for Equipment:
Corrosion or damage to equipment from chemical spills.
Implications for the Environment:
Contamination of air, water, or soil from chemical spills.
4. Ergonomic Hazards
Risks:
Strain from repetitive motions or awkward postures.
Musculoskeletal disorders from lifting heavy objects improperly.
Implications for People:
Chronic pain or long-term disability.
Reduced productivity due to discomfort or injury.
Implications for Equipment:
No direct impact, but improper handling of equipment can lead to
damage.
Implications for the Environment:
Minimal direct impact, but inefficient work practices can lead to
increased waste.
5.Noise Hazards
Risks:
Hearing loss from prolonged exposure to loud machinery.
Implications for People:
Permanent hearing damage or tinnitus.
Increased stress or communication difficulties.
Implications for Equipment:
No direct impact.
Implications for the Environment:
Noise pollution affecting nearby areas.
6. Fire and Explosion Hazards
Risks:
Fires from flammable materials or faulty electrical systems.
Explosions from pressurized equipment or volatile chemicals.
Implications for People:
Burns, injuries, or fatalities.
Implications for Equipment:
Complete destruction of machinery or tools.
Implications for the Environment:
Large-scale environmental damage from fire or chemical release.
7.Slippery or cluttered floors leading to accidents.
Risks:
Slips, Trips, and Falls
Implications for People:
Injuries such as fractures, sprains, or head trauma.
Implications for Equipment:
Damage to equipment from being dropped or struck
during a fall
Implications for the Environment:
Potential spills of hazardous materials if containers are
knocked over.
8. Confined Spaces
Risks:
Asphyxiation or toxic atmospheres in confined spaces.
Implications for People:
Suffocation or poisoning.
Implications for Equipment:
Challenges in equipment operation and maintenance in
confined spaces.
Implications for the Environment:
Accumulation of hazardous gases or materials.
P2.3 describe measures that can be taken to minimize risks
in maintenance workshops
When controlling hazards And minimizing risks, we
focus on the hazard control hierarchy.
The hazard control hierarchy is a systematic approach to
minimizing or eliminating exposure to workplace
hazards.

It consists of several levels, each representing a
different control measure.

The hierarchy typically includes the following levels:
1. Elimination: This involves physically removing the hazard from
the workplace. If the hazard is no longer present, there is no risk of
exposure.
2. Substitution: This involves replacing the hazardous material,
process, or equipment with a less hazardous alternative. This can help
reduce the risk of harm to workers.
3. Engineering Controls: These are physical changes to the
workplace, such as installing barriers, ventilation systems, or noise
enclosures, to isolate people from the hazard.
4. Administrative Controls: These controls involve changing the
way people work, such as implementing policies, procedures, or
training to minimize exposure to hazards.
5. Personal Protective Equipment (PPE): When hazards cannot be
eliminated or substituted, PPE such as gloves, goggles, or respirators
can be used to protect workers from exposure.
7/22/2024
P2.4 carry out and record a RA for a maintenance workshop

7/22/2024
Methods of Risk Assessment
1. Preliminary Hazard Analysis (PHA): This method involves identifying and
evaluating potential hazards at the early stages of a project or process.
2. Failure Mode and Effects Analysis (FMEA): FMEA is a systematic approach
to identifying and preventing potential failures within a system, product, or process.
3. Fault Tree Analysis (FTA): FTA is a deductive approach to analyze the ways in
which an undesired event can occur.
4. Event Tree Analysis (ETA): ETA is a graphical technique used to determine the
possible outcomes of a series of events.
5. Bow-Tie Analysis: This method visually represents the relationship between
causes and consequences of a potential hazard, as well as the control measures in
place to prevent the hazard from occurring.
6. HAZOP (Hazard and Operability Study): HAZOP is a structured and
systematic examination of a process to identify potential hazards and operability
problems.
How to conduct a risk assessment in a maintenance workshop
Step 1: Identify hazards - Identify and list all potential hazards that could cause
harm or damage in the workplace, project, or process.
Step 2: Identify who might be harmed and how - Consider who may be affected
by the identified hazards and how they might be harmed. This includes employees,
visitors, contractors, etc.
Step 3: Evaluate and prioritize risks - Assess the likelihood and severity of the
identified risks. Prioritize the risks based on the level of potential harm and the
likelihood of occurrence.
Step 4: Control measures - Develop and implement control measures to eliminate
or reduce the risks. This may involve engineering controls, administrative controls,
or the use of personal protective equipment (PPE).
Step 5: Record findings - Document the findings of the risk assessment, including
the identified hazards, the risks, and the control measures put in place to mitigate
those risks.
Step 6: Review and update - Regularly review and update the risk assessment,
especially when there are changes in the workplace, processes, or regulations.
 24 June 2019 / ‹#›

Production Shortfall
X < 2 kboe 2 kboe < X < 20 kboe 20 kboe < X < 200 kboe 200 kboe < X < 1 Mboe 1 Mboe < X < 10 Mboe X >10 Mboe
(MAP)

Long-term emission leading to negligible Long-term emission leading to very limited Long-term emission leading to significant Long-term emission leading to very significant Long-term emission leading to extremely
Long-term emission leading to limited potential
Chronic risks (SEES) potential harm to the environment and/or people potential harm to the environment and/or people harm to the environment and/or people off site potential harm to the environment and/or people potential harm to the environment and/or people significant potential harm to the environment
off site off site off site off site and/or people off site

”Notices” in the national media + press agency
Local media (written press, radio, TV). dispatch(es). Negative comments on social
“Report” in the national media; Numerous
Comments on local or national media websites. networks and/or intervention by national “Report” in international media; Negative comments on social networks and/or intervention by
negative comments on social networks and/or
Media No reaction. Information on social networks (Facebook, influencers with more than 500 followers on
interventions by national influencers, in the local
international influencers;
Twitter, discussion forums, etc.) in the local Facebook or Twitter in the local language(s) or Reuse of the event by personalities (political, NGOs, etc.) followed by negative mobilization.
language(s) or the Group’s official languages.
language(s). the Group’s official languages (English and
French).
Severity scale from CR-GR-HSE-801
(Human, Env, Material & Media)
Material X < €20 k €20 k < X < €200 k €200 k < X < €2 M €2 M < X < €10M €10 M < X < €100M X > €100M
Severity scale for Production shortfall & probability
scales from ex-CR EP HSE 102 Temporary exceedance of an emission
Very localized pollution with minimal impact on Pollution of small area with limited impact on the Large-scale pollution in ecosystems of
Pollution with massive and lasting
Environmental standard; accidental spillage below the Group’s Pollution with significant environmental impact. consequences for vast ecosystems of high
the environment. environment. recognized ecological interest.
statistical reporting threshold. ecological interest.

Internal: permanent disability or a fatality. Internal: multiple fatalities. Internal: numerous fatalities.
Recordable incident without lost time, medical Recordable with lost time, including temporary
Human First aid
treatment including restricted work disability (without permanent disability)
External: injuries among local populations. External: one fatality and/or numerous injuries External: multiple fatalities among local
Transport or security related third party fatality. among local population. population.

Severity of Consequence
Production Shortfall Chronic risks
(or Gain) (SEES)
Human, Environmental, Material and Media Minor Moderate Serious Very Serious Catastrophic Disastrous

1 2 3 4 5 6
Incident almost inevitable under
Very likely exposure Very Likely
current conditions (or for gain)
Certain fully successful modification
to long-term Expected to occur several times during plant lifetime
> 10-1 6 6 12 18 24 30 36
emission
outcome
Likelihood of Occurrence

Incident probable with additional
factors (or for gain) High likelihood of Likely exposure to Likely
fully successful modification long-term emission
Could occur several times during over plant lifetime
10-1 - 10-2 5 5 10 15 20 25 30
outcome

Incident possible with additional
Unlikely exposure to Could occur once for every 10 to 20 similar plants Unlikely
factors (or for gain) Some uncertainty
long-term emission over 20 to 30 years of plant lifetime 10-2 - 10-3 4 4 8 12 16 20 24
of successful modification outcome

Combination of rare factors required One time per year for at least 1000 units. One time
Very unlikely Very Unlikely
to cause an incident (or for gain) for every 100 to 200 similar plants in the world over
High uncertainty of successful
exposure to long-
20 to 30 years of plant lifetime. Has already occurred 10-3 - 10-4 3 3 6 9 12 15 18
term emission
modification outcome in the company but corrective action has been taken

Extremely unlikely Has already occurred in the industry but corrective Extremely
Freak combination of factors
required to cause an incident
exposure to long- action Unlikely 2 2 4 6 8 10 12
term emission has been taken 10-4 - 10-5

Event physically possible but has never or seldom
Remote exposure to occurred over a period of 20 à 30 years for a large Remote
No similar incident in industry
long-term emission amount of sites (> few thousands, ex: wagons, < 10-5 1 1 2 3 4 5 6
process drums,…)

Major Consequence
Definitions:
Risk Level 3 Broadly acceptable risk level Risk Level 2 Tolerable risk level if demonstrated to be ALARP Risk Level 1 First Priority, risk level to be obligatorily reduced to Level 2 or 3
 24 June 2019 / ‹#›
PERMIT TO WORK EXAMPLE OF RISK ASSESSMENT
COMMENTS
HAZARDS IDENTIFICATION LINKED TO THE JOB LOCATION
GOLDEN RULES
LINKED TO THE JOB q Classified Area : q 0 ; q 1; q 2; q Non Hazardous
Work at height q Work on scaffold q Presence of: q Liquid HC; q Flammable material
Manual handling q Use of hand tools
q Presence of: q Gaseous HC; q Toxic gas
q Presence of: q Open drain ; q Vent; q Sample point
Lifting: Simple/Routine; Critical (Complicated/Complex)
Work with chemicals / lubricants / paints / solvents q High temperature
q Electrical works; q Instrum & ICSS works q Noisy area
OTHER HAZARDS AND ASSOCIATED RISKS
ADDITIONAL PRECAUTIONS AND PREVENTION MEASURES q Blasting; q Painting; q Dust emission q Automatic actuation of nearby equipment
q Work on Rotating equipment / moving parts
q Live electrical equipment close by; q Aerial power lines
q Use of pressurized tools / hoses (Air, N2, Hydr., water…)
q Interference with adjacent works
q Use or handling of compressed gas (cylinders,…) q Underground network: q pipes; q cables; q culvert
q Use of electri