This document provides an overview of fall protection requirements and best practices. It begins by outlining the course objectives which are to understand definitions of fall prevention, restraint, and arrest; requirements; hazards; and where to seek help. It then discusses statistics on falls as a leading cause of fatalities and injuries in construction. Common fall locations are also outlined. Planning, controlling exposures, systems, hazard recognition, anchorage, and personal protective equipment are all reviewed in detail. The key requirements are that fall protection is required when working 6 feet or more above a lower level in construction or 4 feet in general industry. Proper selection, use, inspection and maintenance of fall protection systems is critical to ensuring worker safety.
2. Course Objectives
Understand the definitions of fall prevention,
fall restraint, and fall arrest.
Understand the requirements of fall
protection.
Recognize the hazards associated with fall
protection.
Know where to seek help and advice for fall
protection (FESHM Chapter 5066)
Fall Protection Refresher Orientation
2
3. Course Objectives
Know how to inspect and wear personal fall
arrest system equipment (PFAS).
Know the requirements for anchorage points
and how to tie off to them.
Fall Protection Refresher Orientation
3
4. What is Fall Protection?
A series of reasonable steps taken to cause
elimination or control of the injurious
effects of an unintentional fall while
accessing or working at height
Fall Protection Refresher Orientation
4
5. Fall Statistics
Falls are the leading cause of fatalities in
the construction industry.
An average of 362 fatal falls occurred each
year from 1995 to 1999, with the trend on
the increase.
The cost of care for injuries related to falls
is a financial burden for the entire
construction industry
Fall Protection Refresher Orientation
5
6. Where Do Fatal Falls Occur
Floors,
Loading
Docks, Ground
Level 4%
Non-moving
Vehicles 3%
Other 12%
Roofs 37%
Structural Steel
9%
Ladders 15%
Fall Protection Refresher Orientation
Scaffolds 20%
6
7. Where Do Non-Fatal Falls Occur
Other 22%
Scaffolds 15%
Roofs 12%
Non-moving
Vehicles 9%
Stairs/Steps
7%
Fall Protection Refresher Orientation
Ladders 35%
7
8. Anatomy of a Fall
.33sec./2 feet
.67 sec./7 feet
1 sec./16 feet
It takes most people about
1/3 of a second to become
aware.
It takes another 1/3 of a
second for the body to
react.
A body can fall up to 7
feet in 2/3 of a second.
2 sec./64 feet
Fall Protection Refresher Orientation
8
9. Planning for Fall Protection
Best practice dictates that fall protection
becomes an integral part of the work
planning process, from constructability, to
systems installation, to use and maintenance
The workplace cannot be truly safe unless
fall protection is incorporated into every
phase of the process
Planning will keep workers safe and
minimize fall exposures
Fall Protection Refresher Orientation
9
10. The Steps of Fall Protection?
Is this the correct order?
Fall Protection Refresher Orientation
10
11. Controlling Fall Exposures
General industry regulations (paraphrased)
• Every open-sided floor, platform, wall opening, or hole 4 feet
or more above adjacent floor or ground level shall be guarded
by a standard railing, or the equivalent, on all open sides
except where there is entrance to a ramp, stairway, or fixed
ladder.
Construction industry regulations (paraphrased)
• Each employee on a walking/working surface (horizontal and
vertical surface) with an unprotected side, edge, or hole which
is 6 feet (1.8 m) or more above a lower level shall be
protected from falling by the use of guardrail systems, safety
net systems, or personal fall arrest systems.
Fall Protection Refresher Orientation
11
12. Controlling Fall Exposures
FESHM Chapter 5066 – Fall Protection Program
• Any worker, visiting scientist, or subcontractor involved in
work activities and exposed to a fall hazard at or greater that
6’ will require fall protection if fall prevention methods
cannot be used.
• 29 CFR 1910 and 29 CFR 1926 shall be followed when the
work involves hazards that require fall protection. There are
requirements that apply to all general work as well as specific
requirements based upon the work activity that is being
performed. Exceptions to fall protection requirements, as
provided in 1926.500, are ONLY for construction-related
activities. There are no fall protection exemptions for
maintenance or operations work.
Fall Protection Refresher Orientation
12
13. Using Fall Protection Systems
Select fall protection systems appropriate for given
situations.
Use proper construction and installation of safety
systems.
Supervise employees properly.
Evaluate the effectiveness of all steps
Use safe work procedures.
Train workers in the proper selection, use, and
maintenance of fall protection systems.
Fall Protection Refresher Orientation
13
14. Fall Protection Methods
Fall Prevention- A system that will prevent a person
from falling to a lower level.
Example: Railings
Work Positioning or Fall Restraint- A system that will
allow the worker to approach a fall hazard and work but
will not allow the worker to fall to a lower level.
Fall Arrest- A system that will protect a person from
crashing on to a lower level after a fall. Example: Fall
Arrest Harness/lanyard
Fall Protection Refresher Orientation
14
15. Competent Person
means one who is capable of identifying
existing and predictable hazards in the
surroundings, or working conditions which
are unsanitary, hazardous, or dangerous to
employees, and who has the authorization
to take prompt corrective measures to
eliminate them.
Fall Protection Refresher Orientation
15
16. Qualified Person
Qualified person" means one with a
recognized degree or professional
certificate and extensive knowledge and
experience in the subject field who is
capable of design, analysis, evaluation and
specifications in the subject work, project,
or product.
Fall Protection Refresher Orientation
16
17. When Is Fall Protection Required?
What are the fall distances that trigger
guardrails and fall protection?
Fall Protection Refresher Orientation
17
18. When Is Fall Protection Required?
Fall
prevention is
required for
falls onto
dangerous
equipment.
Zero fall
distance is
allowed.
Fall Protection Refresher Orientation
18
19. When Is Fall Protection Required?
Fall
protection
is required
for work on
forms or
steel
reinforcing
over 6’ in
height
Fall Protection Refresher Orientation
19
20. When Is Fall Protection Required?
Fall protection is
required for
scaffolding over
6’ in height.
OSHA allows up
to 10’ but the
Lab rule is 6’.
Fall Protection Refresher Orientation
20
21. When Is Fall Protection Required?
Fall
protection
required for
walking /
working
surfaces over
4’ in height
in general
industry
Fall Protection Refresher Orientation
21
22. When Is Fall Protection Required?
Fall
protection
required for
walking /
working
surfaces over
6’ in height
in
construction
Fall Protection Refresher Orientation
22
23. When Is Fall Protection Required?
Fall
protection
is required
for
vertical
ladders
without
cages over
24’
Fall Protection Refresher Orientation
23
24. When Is Fall Protection Required?
No fall protection is
required for portable
extension ladders
Fall Protection Refresher Orientation
24
25. Hazard Recognition
What are the allowable controls
and best practices?
Fall Protection Refresher Orientation
25
26. Walking & Working Surfaces
Hazards with
working/walking
surfaces
• Open-sided floors
• Holes
• Leading edges
Fall Protection Refresher Orientation
26
34. Aerial Work Platforms
A personal fall arrest
system (PFAS) is
required whenever you
are working in an
Articulating and/or
telescoping boom lifts
and bucket trucks
Use the manufacture’s
designated anchorage
points.
Fall Protection Refresher Orientation
34
35. Personal Fall Arrest Systems
Should only be used when other fall
prevention means can not be used or are
not feasible.
Fall Protection Refresher Orientation
35
36. Personal Fall Arrest Systems
Used to protect an employee from hitting a
lower level once they have fallen.
Components include:
•
•
•
•
An anchorage point
Body harness
Deceleration devices
Connectors – lanyards, rope grabs, anchorage
connectors
Fall Protection Refresher Orientation
36
37. Personal Fall Arrest Systems
When using personal fall arrest systems:
• If you fall, the impact force to the body has to be
less than 1800 pounds, achieved by using shock
absorbing lanyards and a harness
• Minimize fall distance, the maximum free fall
distance can only be 6 feet
• There can not be any structures below in you fall
distance
• Maximum weight of an individual w/tools is 310
pounds
Fall Protection Refresher Orientation
37
38. Fall Distances
Free Fall Distance
• The vertical displacement of the fall arrest
attachment point on the employee's harness between
onset of the fall and just before the system begins to
apply force to arrest the fall.
Deceleration Distance
• The distance between the location of an body
harness attachment point at the moment of activation
of the deceleration device during a fall, and the
location of that attachment point after the employee
comes to a full stop.
Fall Protection Refresher Orientation
38
39. Minimizing Free Fall Distance
Extended
Lanyard Length
Plus maximum
2’ extension
(usually within
inches)
6’ Lanyard Length
3.5’ Deceleration Device
Tie to anchor
above the D-ring
Or use a
retractable
Using an anchorage above the D-ring and a standard lanyard may still
allow an employee to fall a distance that may be difficult to rescue
from. Using a retractable minimizes forces on the body, and may
make rescue easier (and therefore more timely)
Fall Protection Refresher Orientation
39
41. Watch Swing Falls
This worker is tied
off using a
retractable lifeline.
There is a major
swing fall potential
if he fell to either
side.
Fall Protection Refresher Orientation
Swing Fall
41
42. Personal Fall Arrest Systems
Anchorage
Body
Connector
Harnesses
Caribiners
Rope
Grabs
Beam
Wraps
Lanyards
Fall Protection Refresher Orientation
42
Positioning
43. Anchorages
Fall arrest anchor points must support 5000 lbs
per employee attached
Fall restraint anchor points must support at least
1000 lbs per employee attached
Ask your supervisor, Senior Safety Officer, or the
ESH–Section safety representatives if you need
assistance in determining an adequate anchorage
point
Fall Protection Refresher Orientation
43
44. Roof & Deck Anchors
Permanent
Anchors
Wood Roof
Anchor
Metal Roof
Anchor
Fall Protection Refresher Orientation
44
45. Use of Eye Bolts
Rated for loading
parallel to the bolt
axis.
If wall mounted, the
rating perpendicular to
the axis must be good
for 5,000 lbs. per
employee
Fall Protection Refresher Orientation
Rated
Needed
45
46. Girder Grip Anchorage Rings
Fall Protection Refresher Orientation
These attachments can be
mounted through bolt holes
on steel members.
They are rated at 5,000 lbs.
in all directions
46
47. Removable Concrete Anchors
These attachments can be mounted in holes of concrete.
They are rated at 5,000 lbs. in all directions
Fall Protection Refresher Orientation
47
48. Anchorage Connectors
These type of connectors enable you to tie off to various
types of anchorage points
Fall Protection Refresher Orientation
48
49. Beam Clamps
Beam clamps can make an effective anchorage when used properly, and with
the correct lanyard
TIGHT
BEAM
CLAMP
PIN SET
Be sure pin is inserted full length and clamp
is tight.
Fall Protection Refresher Orientation
49
50. Horizontal Life Lines
Provide maneuverability
Must be designed, installed and used under the guidance of a
qualified person
• This could be interpreted as requiring the use of manufactured systems,
which is recommended
Fall Protection Refresher Orientation
50
51. Horizontal Line Engineering
72,000 lb
72,000 lb
5,000 lb
5,000 lb
Anchor stress depends on the sag angle of the line.
Fall Protection Refresher Orientation
51
52. Line Stanchions
5,000lb.
The connection of
the line stanchion
to the flange must 3 ft.
support the
bending moment
applied to the base.
Fall Protection Refresher Orientation
Bending
Moment
15,000 ft-lb
52
53. Aerial Work Platform Anchorages
Use the manufacture’s designated anchorage points.
Never use guardrails as anchorage points.
Fall Protection Refresher Orientation
53
54. Body Harness
Need to be inspected before use by the
worker, and at least annually (documented)
by a Competent Person
Harnesses should never be modified
Do not write on or paint harnesses unless
material is approved for use
Should be taken out of service immediately
if defective or exposed to an impact
Fall Protection Refresher Orientation
54
55. Harness Fitting
Chest strap tightened
at mid chest
“D” ring between
shoulder blades
Proper snugness
shoulder to hips
Butt strap
supports the load
Leg straps snug but
not binding
Harnesses must be sized for the worker. Workers must
weigh more than 130 lbs. and less than 300lbs.
Fall Protection Refresher Orientation
55
56. Harness Pressure Points
Spread load
across butt strap
and belt strap if
on the harness
Excess pressure here can
cut blood flow to the legs
Some studies have indicated permanent damage to the lower extremities
when the worker hangs for more than twenty (20) minutes
Fall Protection Refresher Orientation
56
57. Deceleration Devices
Any mechanism with a maximum length of
3.5 feet, such as a rope grab, rip stitch
lanyard, tearing or deforming lanyards, selfretracting lifelines, etc. which serves to
dissipate a substantial amount of energy
during a fall arrest, or otherwise limit the
energy imposed on an employee during fall
arrest.
Fall Protection Refresher Orientation
57
58. Lanyards
A flexible line of rope, wire rope, or strap which
generally has a connector at each end for
connecting the body belt or body harness to a
deceleration device, lifeline or anchorage.
Must not be tied back to themselves unless
specifically designed for such use
Should have the appropriate clip for the intended
anchorage points
Do not knot or wrap around sharp objects
Fall Protection Refresher Orientation
58
60. Retractable Lifelines
Deceleration devices containing a
drum-wound line which can be
slowly extracted from, or retracted
onto, the drum under slight tension
during normal employee
movement, and which, after onset
of a fall, automatically locks the
drum and arrests the fall.
Do not use with energy absorbing
lanyards.
Fall Protection Refresher Orientation
60
61. Lifelines
A component consisting of a flexible line for
connection to an anchorage at one end to hang
vertically or for connection to anchorages at
both ends to stretch horizontally and which
serves as a means for connecting other
components of a personal fall arrest system to
the anchorage.
Fall Protection Refresher Orientation
61
62. Positioning Systems
Positioning devices
provide hands-free
work
• Additional fall
protection may be
required to move or
access
Fall Protection Refresher Orientation
62
63. Restraint Devices
Provide access but prevent the fall
Limit anchorage requirement to 1000 lbs
May be more suitable for loading areas,
scaffold erection and dismantling
Should be installed and used under the
supervision of a Competent Person
Fall Protection Refresher Orientation
63
64. Fall Restraint
Restraint Line
Edge
Fall restraint assumes the employee cannot reach the edge, they
are basically on a short leash.
If the employee can fall over the edge, then a personal fall arrest
system must be used.
Fall Protection Refresher Orientation
64
65. Use of Restraint Cables
Example of restraint cables used during deck anchoring.
RESTRAINT CABLE
Fall Protection Refresher Orientation
65
66. Planning For A Rescue
Whenever working
with the potential of
hanging by a harness,
a rescue plan must be
in effect.
A written Hazard
Analysis must be
done and employees
must be trained on
the plan.
Fall Protection Refresher Orientation
66
67. Planning For A Rescue
The rescue plan must be written in the hazard
analysis
The goal is to rescue the employee as soon as
possible and limit the hanging time to no more
than fifteen minutes.
Plan for a worker that is unconscious.
Ensure all the rescue equipment in the vicinity
Call x3131whenever someone has been in a
fall arrest situation
Fall Protection Refresher Orientation
67
68. Fall Protection
For any additional information or questions
regarding this presentation call:
Rafael Coll
ES&H Section
rcoll@fnal.gov
Ext: 8518
Fall Protection Refresher Orientation
John Cassidy
ES&H Section
jcassidy@fnal.gov
Ext: 8223
68
Editor's Notes
Welcome to Fall Protection Refresher Training. It takes more than talk to understand the do’s and don'ts of a fall protection program. Not understanding the hazards and or not using equipment properly can lead serious injury or death when it comes to protecting yourself from a fall.
At the end of this presentation you should know the difference between fall prevention, fall restraint, and fall arrest.
We will review the hazards associated with fall protection and how to mitigate those hazards.
We will discuss the requirements of Fermilab’s fall protection program and where you can seek help if you have any questions or concerns regarding fall protection.
We will review anchorage points requirements and types of connectors.
You will learn how to inspect your personal fall arrest equipment and how to properly don your equipment.
After the slide presentation you will watch a short video titled The ABC’s of Fall Protection.
Once you have reviewed all the course material you must request and pass the online quiz to receive credit.
Fall protection is the process where measures are taken, such as guardrails, fall restraint, or personnel fall arrest systems, to ensure employees do not fall from elevations over four feet.
Falls are the leading cause of fatalities in the construction industry. You may expose to falls from activities other than construction. You may be working with an experiment, doing preventive maintenance, or working out of an articulating lift.
We may spend a great deal of time discussing fatal falls, and their affect on industry, but…
… the frequency of falls is an equally important issue. Many employees throughout the US have been seriously injured in falls from ladders, scaffolds, etc.
Fall are unexpected and the time it takes to strike a lower level surface is frightfully fast.
Whether you are working at CDF, performing maintenance on equipment at heights, or working at heights on a construction project, you have to plan your work with the goal of eliminating any chance of a fall.
When it comes to planning for fall protection, what would be the proper order of these methods?
Prevention should be first – always strive to prevent the fall
Positioning, including restraint, should be second, to provide safe access to the work location. Fall arrest may also be required
Fall arrest is employed after the fall, so is one of the least-desirable approaches, assuming, as it does, that an employee will fall and that all systems will function properly to arrest the fall.
Retrieval assumes the fall arrest system has already worked, and must be employed as quickly as possible to minimize further injury or damage.
The key is that all steps must be taken as part of a systematic approach to fall protection, but the most effort and priority should be applied to preventing falls in the first place
We follow the OSHA standards at Fermilab and there are different heights where action is required. It is up to management to decide if work will be defined as construction. In either case, the goal is to provide a safe work environment were employees are protected from falls the could result in serious injury. Only a systematic approach to fall exposures will help to minimize the potential for falls
Fermilab’s ESH Manual Chapter 5066 simply states, “any employee, user, visiting scientist, involved in work activities that expose them to a fall hazard at or greater than four feet will be protected by a fall protection system.
When using fall protection systems, the correct system needs to be selected for the given situation.
The system needs to be installed properly
Workers need to be supervised and observed to ensure safe work procedures
Anyone using personal fall arrest equipment must be trained on the use of the equipment and have an understanding of the hazards present.
Fall protection systems need to be evaluated and assessed by management
The different types of fall protection methods include;
fall prevention - a system design to prevent a worker from falling to a lower level such as guardrails;
work positioning or fall restraint - a system that uses personal fall arrest equipment but is designed to let a work approach a fall hazard but not fall to a lower level;
fall arrest - a system that will prevent a worker from crashing to a lower level in the event they do fall, such as a body harness and shock absorbing lanyard.
Fall protection systems must be overseen by competent persons. This is generally the responsibility of the supervisor.
Qualified persons, as defined in fall protection systems, is a person who has a recognized degree or professional certificate and extensive knowledge and experience in the subject field who is capable of design, analysis, evaluation and specifications in the subject work, project, or product. For example a qualified person would be needed to design lifeline systems and determine anchorage points.
What fall distances trigger the measures that need to be taken for guardrails and fall protection?
Zero fall distance is allowed for working around dangerous equipment. Dangerous equipment is defined as equipment (such as pickling or galvanizing tanks, degreasing units, machinery, electrical equipment, and other units) which, as a result of form or function, may be hazardous to employees who fall onto or into such equipment.
In construction, working on forms or reinforcing steel over six feet requires fall protection measures.
OSHA allows workers in construction working on scaffolding to work at heights up to ten feet without fall protection but at Fermilab we require workers to have fall protection at six feet.
The general industry standard, which applies to any Lab work not deemed construction, requires fall protection at four feet.
Any walking/working surface on a construction site requires fall protection measures starting at six feet.
Vertical ladders over twenty-four feet without cages require fall protection.
Use of portable extension ladders are not covered under the fall protection standard because they have their own standard in the OSHA General Industry and Construction Standards
Lets take a look at actual photographs to get a better understanding of controls and best practices for fall protection.
Fall hazards on working and walking surfaces can be open-sided floors, holes, and leading edges.
In the photograph is that a lanyard, or the vacuum cord hanging down?
What is the worker anchored to?
How far can he fall?
Did he use the swing stage to access this work location? Is that a hazard?
There are lots of questions, but the answer to this situation is, proper work planning was needed to eliminate the hazards.
Open sided floors should be protected by guardrails, as pictured on the right. If not feasible, fall restraint can be used as shown in the photograph on the left side.
When guardrails are used for fall prevention they must be forty-two inches high, plus or minus three inches, they must support 200 lbs in an outward or downward direction. Wood surfaces must be smooth and all posts cut flush to prevent injury.
The photograph on the left is not adequate because of gaps at end of rails and extension beyond posts. The right photograph shows a properly built guardrail.
Cable guardrail is sometimes used on the job and it must meet the minimum requirements. It has to be at forty-two inches high and cannot deflect below thirty-nine inches. It has to be marked every six feet so it is easily visible. It must have adequate terminations and attachments. These types of guardrails do require maintenance to ensure they remain functional.
Ladder access is sometimes required to lower levels and proper work planning can eliminate floor openings. The ladder way requires fall protection, with a maximum opening of eighteen inches to the side of the ladder, or an offset entry to minimize the hazard of employees “stumbling” into the opening
Holes in floors need to be guarded with railing or covered. Covers must be clearly marked, secured to prevent displacement, and capable of supporting twice the intended load.
Ideally, barricades prevent access to the skylights. If covers are provided, they must support twice the intended load.
The photo on the right is a person sat on a skylight to eat his lunch, and fell through. When accessing a roof all hazards must be identified.
When working in articulating and/or telescoping boom lifts or bucket trucks you are required to wear a personal fall arrest system. Make sure you use a fall restraint system that prevents you from leaving the work platform or bucket. When you tie off only use the manufacture’s designated tie off point. Consult the manufacture’s user manual if needed.
Proper work planning can eliminate most situations where a personal fall arrest system is required. Most likely you will experience some type of injury if you are involved in a fall event. Personal fall arrest systems should only be used when other fall prevention means cannot be used or are not feasible.
When using fall arrest equipment a person can not be subjected to more than 1800 lbs of force and this is achieved by using a body harness and an energy absorbing lanyard. You can not be exposed to a free fall of more than six feet and there must not be anything beneath you that you could strike.
There are weight limitations. The weight range for users of personal fall arrest systems is 130 -310 pounds.
Free fall distance is the distance someone falls before the fall arrest equipment begins to engage.
Deceleration distance is the distance someone falls once the fall arrest equipment engages to the point in which they come to a complete stop.
Total fall distance is the sum of the free fall distance and the deceleration distance.
Persons using fall arrest equipment should always position their anchorage point above the D-ring to minimize the free fall distance. The illustration above demonstrates how minimizing the free fall distance can be achieved. The use of retractable lanyards is always preferred when using fall arrest equipment because the total fall distance is usually two feet or less.
This diagram shows the way to calculate the total fall distance. You add the length of the lanyard, plus the deceleration distance, plus the height of the worker (which generally is the height of the D ring and harness stretch), plus the safety factor. In the diagram the total fall distance would be calculated to eighteen and half feet.
When using retractable lanyards be aware of the hazard of swing falls. When the retractable lanyard is out, make sure you are not able to fall where the lanyard can not stop you from falling more the two feet.
The photograph shows the basic components of a personal fall arrest system.
Depending on the application and type of personal fall arrest system, the strength of the anchorage point can vary. When using fall arrest equipment where the is the potential to fall the anchorage point must withstand five thousand pounds of pull per employee. If two people are attached to the same anchorage point the strength must be at least ten thousand pounds.
Anchorage point strengths for fall restraint is one thousand pounds, much less than the five thousand pounds required for fall arrest anchorage points. This is because when using fall restraint there in no danger of a fall.
Remember, you can always contact an ESH representative for assistance in determining anchorage points.
Here are some pictures of different types of anchorage devices for roof and deck applications. You can only install these devices if you are qualified. Remember, the definition of qualified persons as defined in fall protection systems, is a person who has a recognized degree or professional certificate and extensive knowledge and experience in the subject field who is capable of design, analysis, evaluation and specifications in the subject work, project, or product.
Eye bolts can be used for anchorage points but their design and application must be completed by a qualified person.
Manufactured anchorage rings or connectors are already designed and rated and can be used by anyone following the installation directions.
Here is another type of manufactured anchorage ring that is already designed and rated and can be used by anyone following the installation directions.
Anchorage connectors are designed to hook onto or wrap around structures or equipment. The structure or equipment you attach these type of connectors must be rated for five thousand pounds of static weight for fall arrest and one thousand pounds for fall restraint. Other things to consider are types of material and sharp edges that could create a hazard if a fall occurred. Over head locations are best for these connectors because it decreases the free fall distance.
While you may not typical use beam clamps it is good to know how they are applied. What happens when the employee reaches the next joist? They need a second beamer to make the traverse over the joist end, otherwise will not be tied off 100% of the time. Also, some prefabricated building rafters/joists may not be suitable for the application of a beamer, as the flange is too thin to support the potential impact.
Horizontal lifelines must be designed, installed, and used, under the supervision of a qualified person, as part of a complete personal fall arrest system, which maintains a safety factor of at least two. There are limitations on how many people can be connected to a horizontal lifeline. Check with your supervisor or you ESH representative on any restrictions.
The diagram shows the different stresses on anchorage points for horizontal lifelines. The qualified person designing such systems need to consider many factors, including potential sag of the lifeline.
Lifeline stanchions also require special design considerations for a qualified person as indicated in this diagram.
When using articulating and or telescoping boom lifts fall restraint equipment is required. A full body harness with a 2-foot lanyard works as restraint device preventing the user from being thrown from the bucket or basket area.
Body harnesses must be inspected by the user before use. A documented annual inspection by a competent person is required as well. It is the responsibility of each Division/ Section to perform these annual inspections on their equipment.
A properly fitted harness is essential to minimize the shock to the body if you were exposed to a fall arrest. Harnesses do have limitations, if you are over three hundred ten pounds and under one hundred thirty pounds you will need specialized equipment. See your supervisor or your ESH representative for assistance if you do not fall within these parameters.
If you are suspended by your fall arrest equipment you must be aware of the potential hazards of orthostatic intolerance. Excessive pressure from the straps can cut off blood flow to the legs and cause permanent damage after hanging for fifteen minutes. Some harnesses are equipped with step in straps designed to relieve these pressure points if a worker is hanging. Be sure to know how to use this type of equipment if you have it.
Deceleration devices, also known as shock absorbing or energy absorbing lanyards are designed to slow the free fall before coming to a stop thereby reducing the impact on the body. Even with these type of lanyards the force on the body can be up to eighteen hundred pounds.
Only use the lanyard in accordance with the manufactures recommendations. Do not tie the lanyard back to itself unless it is design to do so. The clips must be designed for the type of anchorage point you are using. And as with any synthetic material equipment, do not use against sharp edges or objects.
Here are a few types of energy absorbing lanyards
Retractable lifelines are devices design to lock on the onset of a fall. It works similar to a vehicle safety belt in that it locks when the line is pulled at a rate faster than normal movement. The length of retractables vary so you must be aware of the potential swing fall hazards since you can have many feet of line extended out. Never use energy absorbing lanyards with this type of equipment.
The lifeline is used to connect a personal fall arrest system (consisting of a harness and deceleration lanyard) to an anchor point that cannot be reached by the short lanyard. The lanyard/lifeline connection point in a sense becomes the anchor point. The lifeline is not intended to stretch to add to the length of a fall.
The lifeline can be made of a flexible line such as a rope or cable, or it can be made of a strap or webbing material.
Lifelines can hang vertically from an anchor point and horizontally between two anchor points.
Positioning systems are design for use on vertical surfaces. It gives the worker the ability to work with both hands while be suspended with no free fall hazard. Typically this application is used in vertical rebar work but can be used in other situations where vertical access is required.
If guardrails are not feasible then fall restraint is the next best way to work if you are exposed to a fall hazard. Restraint systems must be installed and used under the supervision of a competent person. Because no free fall hazard is possible in restraint systems, the anchorage point requirement is one thousand pounds.
This is how a fall restraint system should be designed.
Here are two photographs of actual applications of a fall restraint system.
Whenever working at heights where there is a potential of hanging from a harness after a fall, a written hazard analysis is required. In the HA, there must be a rescue plan to retrieve someone hanging from a harness within a short period of time.
The goal of any rescue is to limit the hanging/suspension time of the fallen employee. With a harness, the suspension time is a maximum of 15 minutes, less is desirable.
The plan should address the fact the worker may be unconscious.
Ensure all the rescue equipment is in place or ready to be put in place.
Notify the Fermilab Fire Department prior to starting work so they can be prepared to respond. Have them assist you in developing a plan if needed.
Ensure everyone is aware of the plan.
If you need any additional information or assistance please contact Rafael Coll or John Cassidy of the ESH Section .