Steingass Mechanical Contracting, Inc. 754 Progress Drive
Medina, Ohio 44256 (330) 725-6090
SCAFFOLD
REQUIREMENTS
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SCAFFOLDS
INTRODUCTION
The Occupational Safety and Health Act under 29 CFR 1926 Subpart L establishes requirements
to address the hazards associated with the use of scaffolding. In response to the regulatory
mandate Steingass Mechanical Contracting, Inc. has developed and will maintain the Scaffolding
Program to provide the proper and safe procedures for all applicable employees.
PURPOSE
This document is primarily intended to outline the methods of protecting and/or informing all
employees engaged in the use of scaffolds. In addition, it is intended that Steingass Mechanical
Contracting, Inc. will be in full compliance with 29 CFR 1926 Subpart L.
Due to the serious nature of this policy, Steingass Mechanical Contracting, Inc. intends to
continually monitor this policy for its workability and identify inadequacies or deficiencies.
RESPONSIBILITY
Steingass Mechanical Contracting, Inc. shall instruct all applicable employees in the safety
significance of the Scaffold Program and/or procedures. In addition, Steingass Mechanical
Contracting, Inc. considers these requirements to be of critical importance in helping to ensure
that the applicable provisions of the Scaffold Program are known, understood, and strictly
adhered to by all employees. Strict enforcement of this program is required as a condition of
employment. Any variations from these set procedures will be considered a work rule violation
and because of the serious nature of this program, disciplinary action will be taken in accordance
with the disciplinary guidelines described in Steingass Mechanical Contracting, Inc. Safety Rules
and Regulations.
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DEFINITIONS
Adjustable suspension scaffold: A suspension scaffold equipped with a hoists(s) that can be
operated by an employee(s) on the scaffold.
Bearer (putlog): A horizontal transverse scaffold member (which may be supported by ledgers
or runners) upon which the scaffold platform rests and which joins scaffold uprights, posts, poles
and similar members.
Boatswains' chair: A single-point adjustable suspension scaffold consisting of a seat or sling
designed to support one employee in a sitting position.
Body belt (safety belt): A strap with means both for securing it about the waist and for attaching
it to a lanyard, lifeline or deceleration device.
Body harness: A design of straps which may be secured about the employee in a manner to
distribute the fall arrest forces over at least the thighs, pelvis, waist, chest and shoulders, with
means for attaching it to other components of a personal fall arrest system.
Brace: A rigid connection that holds one scaffold member in a fixed position with respect to
another member or to a building or structure.
Bricklayers' square scaffold: A supported scaffold composed of framed squares which support
a platform.
Carpenters’ bracket scaffold: A supported scaffold consisting of a platform supported by
brackets attached to building or structural walls.
Catenary scaffold: A suspension scaffold consisting of a platform supported by two essentially
horizontal and parallel ropes attached to structural members of a building or other structure.
Additional support may be provided by vertical pickups.
Chimney hoist: A multi-point adjustable suspension scaffold used to provide access to work
inside chimneys. (See “multi-point adjustable suspension scaffold”.)
Cleat: A structural block used at the end of a platform to prevent the platform from slipping off
its supports. Cleats are also used to provide footing on sloped surfaces such as crawling boards.
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Competent person: 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 authorization to take prompt corrective measures to eliminate them.
Continuous run scaffold (run scaffold): A two-point or multi-point adjustable suspension
scaffold constructed using a series of interconnected braced scaffold members or supporting
structures erected to form a continuous scaffold.
Coupler: A device for locking together the tubes of a tube and coupler scaffold.
Crawling board (chicken ladder): A supported scaffold consisting of a plank with cleats
spaced and secured to provide footing for use on sloped surfaces such as roofs.
Deceleration device: Any mechanism, such as a rope grab, rip-stitch lanyard, specifically-
woven lanyard, tearing or deforming lanyard or automatic self-retracting lifeline lanyard, which
dissipates a substantial amount of energy during a fall arrest or limits the energy imposed on an
employee during fall arrest.
Double pole (independent pole) scaffold: A supported scaffold consisting of a platform(s)
resting on cross beams (bearers) supported by ledgers and a double row of uprights independent
of support (except ties, guys, braces) from any structure.
Equivalent: Alternative designs, materials or methods to protect against a hazard, which the
employer can demonstrate, will provide an equal or greater degree of safety for employees than
the methods, materials or designs specified in the standard.
Exposed power lines: Electrical power lines which are accessible to employees and which are
not shielded from contact. Such lines do not include extension cords or power tool cords.
Eye or eye splice: A loop with or without a thimble at the end of a wire rope.
Fabricated decking and planking: Manufactured platforms made of wood (including laminated
wood and solid sawn wood planks), metal or other materials.
Fabricated frame scaffold (tubular welded frame scaffold): A scaffold consisting of a
platform(s) supported on fabricated end frames with integral posts, horizontal bearers and
intermediate members.
Failure: Load refusal, breakage, or separation of component parts. Load refusal is the point
where the ultimate strength is exceeded.
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Float (ship) scaffold: A suspension scaffold consisting of a braced platform resting on two
parallel bearers and hung from overhead supports by ropes of fixed length.
Form scaffold: A supported scaffold consisting of a platform supported by brackets attached to
formwork.
Guardrail system: A vertical barrier, consisting of, but not limited to, toprails, midrails and
posts, erected to prevent employees from falling off a scaffold platform or walkway to lower
levels.
Hoist: A manual or power-operated mechanical device to raise or lower a suspended scaffold.
Horse scaffold: A supported scaffold consisting of a platform supported by construction horses
(saw horses). Horse scaffolds constructed of metal are sometimes known as trestle scaffolds.
Independent pole scaffold: (see “double pole scaffold”).
Interior hung scaffold: A suspension scaffold consisting of a platform suspended from the
ceiling or roof structure by fixed length supports.
Ladder jack scaffold: A supported scaffold consisting of a platform resting on brackets
attached to ladders.
Ladder: A platform at the end of a flight of stairs.
Landing: A platform at the end of a flight of stairs.
Large area scaffold: A pole scaffold, tube and coupler scaffold, systems scaffold, or fabricated
frame scaffold erected over substantially the entire work area. For example: a scaffold erected
over the entire floor area of a room.
Lean-to scaffold: A supported scaffold, which is kept erect by tilting it toward and resting it
against a building or structure.
Lifeline: A component consisting of a flexible line that connects to an anchorage at one end to
hang vertically (vertical lifeline), or that connect to anchorages at both ends to stretch
horizontally (horizontal lifeline), and which serves as a means for connecting other components
of a personal fall arrest system to the anchorage.
Lower levels: Areas below the level where the employee is located and to which an employee
can fall. Such areas include, but are not limited to, ground levels, floors, roofs, ramps, runways,
excavations, pits, tanks, materials, water and equipment.
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Masons’ adjustable supported scaffold: (see “Self-contained adjustable scaffold”).
Masons’ multi-point adjustable suspension scaffold: A continuous run suspension scaffold
designed and used for masonry operations.
Maximum intended load: The total load of all persons, equipment, tools, materials, transmitted
loads, and other loads reasonably anticipated to be applied to a scaffold or scaffold component at
any one time.
Mobile scaffold: A powered or unpowered, portable, caster or wheel-mounted supported
scaffold.
Multi-level suspended scaffold: A two-point or multi-point adjustable suspension scaffold with
a series of platforms at various levels resting on common stirrups.
Multi-point adjustable suspension scaffold: A suspension scaffold consisting of a platform(s),
which is suspended by more than two ropes from overhead supports and equipped with, means to
raise and lower the platform to desired work levels. Such scaffolds include chimney hoists.
Needle beam scaffold: A platform suspended from needle beams.
Open side and ends: The edges of a platform that are more than 14 inches away horizontally
from a sturdy, continuous, vertical surface (such as a building wall) or a sturdy, continuous
horizontal surface (such as a floor), or a point of access. Exception: For plastering and lathing
operations, the horizontal threshold distance is 18 inches.
Outrigger: The structural member of a supported scaffold used to increase the base width of a
scaffold in order to provide support for and increased stability of the scaffold.
Outrigger beam (thrust out): The structural member of a suspension scaffold or outrigger
scaffold which provides support for the scaffold by extending the scaffold point of attachment to
a point out and away from the structure or building.
Outrigger scaffold: A supported scaffold consisting of a platform resting on outrigger beams
(thrust outs) projecting beyond the wall or face of the building or structure, the inboard ends of
which are secured inside the building or structure.
Overhand bricklaying: The process of laying bricks and masonry units such that the surface of
the wall to be jointed is on the opposite side of the wall from the mason, requiring the mason to
lean over the wall to complete the work. It includes mason tending and electrical installation
incorporated into the brick wall during the overhand bricklaying process.
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Personal fall arrest system: A system used to arrest an employee’s fall. It consists of an
anchorage, connectors, a body belt or body harness and may include a lanyard, deceleration
device, lifeline or combination of these.
Platform: A work surface elevated above lower levels. Platforms can be constructed using
individual wood planks, fabricated planks, fabricated decks and fabricated platforms.
Pole scaffold: (see definitions for “single-pole scaffold” and “double-pole scaffold”).
Power operated hoist: A hoist, which is powered by other than human energy.
Pump jack scaffold: A supported scaffold consisting of a platform supported by vertical poles
and movable support brackets.
Qualified: One who, by possession of a recognized degree, certificate, or professional standing,
or who by extensive knowledge, training and experience, has successfully demonstrated his/her
ability to solve or resolve problems related to the subject matter, the work, or the project.
Rated load: The manufacturer’s specified maximum load to be lifted by a hoist or to be applied
to a scaffold or scaffold component.
Repair bracket scaffold: A supported scaffold consisting of a platform supported by brackets
which are secured in place around the circumference or perimeter of a chimney, stack, tank or
other supporting structure by one or more wire ropes placed around the supporting structure.
Roof bracket scaffold: A rooftop supported scaffold consisting of a platform resting on
angular-shaped supports.
Runner (ledger or ribbon): The lengthwise horizontal spacing or bracing member, which may
support the bearers.
Scaffold: Any temporary elevated platform (supported or suspended) and its supporting
structure (including points of anchorage), used for supporting employees or materials or both.
Self-contained adjustable scaffold: A combination supported and suspension scaffold
consisting of an adjustable platform(s) mounted on an independent supporting frame(s) not a part
of the object being worked on, and which is equipped with a means to permit the raising and
lowering of the platform(s). Such systems include rolling roof rigs, rolling outrigger systems,
and some masons’ adjustable supported scaffolds.
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Shore scaffold: A supported scaffold, which is placed against a building or structure and held
in place with props.
Single-point adjustable suspension scaffold: A suspension scaffold consisting of a platform
suspended by one rope from an overhead support and equipped with means to permit the
movement of the platform to desired work levels.
Single-pole scaffold: A supported scaffold consisting of a platform(s) resting on bearers, the
outside ends of which are supported on runners secured to a single row of posts or uprights and
the inner ends of which are supported on or in a structure or building wall.
Stair tower (scaffold stairway/tower): A tower comprised of scaffold components and which
contains interval stairway units and rest platforms. These towers are used to provide access to
scaffold platforms and other elevated points such as floors and roofs.
Stall load: The load at which the prime mover of a power-operated hoist stalls or the power to
the prime mover is automatically disconnected.
Step, platform, and trestle ladder scaffold: A platform resting directly on the rungs of
stepladders or trestle ladders.
Stilts: A pair of poles or similar supports with raised footrests, used to permit walking above
the ground or working surface.
Stone setters’ multi-point adjustable suspension scaffold: A continuous run suspension
scaffold designed and used for stone setters’ operations.
Supported scaffold: One or more platforms supported by outrigger beams, brackets, poles, legs,
uprights, posts, frames or similar rigid support.
System scaffold: A scaffold consisting of posts with fixed connection points that accept
runners, bearers, and diagonals that can be interconnected at predetermined levels.
Top plate bracket scaffold: A scaffold supported by brackets that hook over or are attached to
the top of a wall. This type of scaffold is similar to carpenters’ bracket scaffolds and form
scaffolds and is used in residential construction for setting trusses.
Tube and coupler scaffold: A supported or suspended scaffold consisting of a platform(s)
supported by tubing, erected with coupling devices connecting uprights, braces, bearers and
runners.
Tubular welded frame scaffold: (see “fabricated frame scaffold”).
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Two-point suspension scaffold (swing stage): A suspension scaffold consisting of a platform
supported by hangers (stirrups) suspended by two ropes from overhead supports and equipped
with means to permit the raising and lowering of the platform to desired work levels.
Unstable objects: Items whose strength, configuration, or lack of stability may allow them to
become dislocated and shift and therefore may not properly support the loads imposed on them.
Unstable objects do not constitute a safe base support for scaffolds, platforms or employees.
Examples include, but are not limited to: barrels, boxes, loose brick and concrete blocks.
Vertical pickup: A rope used to support the horizontal rope in catenary scaffolds.
Walkway: A portion of a scaffold platform used only for access and not as a work level.
Window jack scaffold: A platform resting on a bracket or jack, which projects through a
window opening.
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GENERAL REQUIREMENTS
CAPACITY
1. Each scaffold and scaffold component will be capable of supporting its own weight and
at least 4 times the maximum intended load.
2. Direct connections to roofs and floors and counterweights used to balance adjustable
suspension scaffolds will be capable of resisting at least 4 times the tipping moment
imposed by the scaffold operating at the rated load of the hoist or 1 ½ times the tipping
moment imposed by the scaffold operating at the stall load of the hoist, whichever is
greater.
3. Each suspension rope (including connecting hardware) used on non-adjustable
suspension scaffolds will be capable of supporting at least 6 times the maximum intended
load.
4. Each suspension rope (including connecting hardware) used on adjustable suspension
scaffolds will be capable of supporting at least 6 times the maximum intended load with
the scaffold operating at either the rated load of the hoist or at least 2 times the stall load
of the hoist, whichever is greater.
5. The stall load of any scaffold hoist will not exceed 3 times its rated load.
6. Scaffolds will be designed by a qualified person and be built and loaded according to that
design.
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SCAFFOLD PLATFORM CONTRUCTION
1. Each platform on all working levels will be fully planked or decked between the front
uprights and the guardrail supports as follows:
a. Each platform unit will be installed so that the space between adjacent units and
the space between the platform and the uprights is no more than one inch.
b. If a wider space is necessary (for example, to fit around uprights when side
brackets are used to extend the width of the platform) the platform will be planked
or decked as fully as possible and the remaining open space will not exceed 9-1/2
inches.
2. Each scaffold platform and walkways will be at least 18 inches wide; except
a. Ladder jack scaffolds, top plate bracket scaffolds, roof bracket scaffold and pump
jack scaffolds will be at least 12 inches wide.
b. There is no minimum width requirement for boatswains' chairs.
c. When scaffolds are used in areas demonstrated to be so narrow that platforms and
walkways cannot be at least 18 inches wide, platforms and walkways will be as
wide as feasible and employees will be protected from fall hazards by the use of
guardrails and/or personal fall arrest systems.
3. The front edge of all platforms will not exceed 14 inches from the face of work, except
the following:
a. Outrigger scaffolds - maximum distance of 3 inches.
b. Plastering and lathing operations - maximum distance of 18 inches.
c. Guardrails are erected along the front edge or personal fall arrest systems are
used.
4. Each end of a platform unless cleated or restrained by hooks, will extend over the
centerline of its support at least 6 inches.
a. Each end of a platform with a length of 10 feet or less will not extend over its support
more than 12 inches unless the platform is designed and installed so that the
cantilevered portion of the platform is able to support employees and/or materials
without tipping;
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b. Each end of a platform with a length of greater than 10 feet will not extend over
its support more than 18 inches unless the platform is designed and installed so
that the cantilevered portion of the platform is able to support employees and/or
materials without tipping.
5. Where scaffold planks are abutted to create a long platform, each abutted end will rest on
a separate support surface.
6. Where platforms are overlapped to create a long platform, the overlap will occur only
over supports and will not be less than 12 inches unless the platforms are nailed together
to prevent movement.
7. At all points of a scaffold where the platform changes direction, such as turning a corner,
any platform that rests on a bearer at an angle other than a right angle will be laid first
and platforms which rest at right angles over the same bearer will be laid second (on top
of the first platform).
8. Wood platforms will not be covered with opaque finishes, except that platform edges
may be covered or marked for identification purposes. Platforms may be coated
periodically with wood preservatives, fire-retardant finishes and slip-resistant finishes.
The coating may not obscure the top of bottom wood surfaces.
9. Scaffold components manufactured by different manufacturers will not be intermixed
unless the components fit together without force and the scaffold's structural integrity is
maintained by the use. Scaffold components manufactured by different manufacturers
will not be modified in order to intermix them unless the competent person determines
the resulting scaffold is structurally sound.
10. Scaffold components made of dissimilar metals will not be used together unless the
competent person has determined that galvanic action will not reduce the strength of any
component.
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CRITERIA FOR SUPPORTED SCAFFOLDS
1. Supported scaffolds with a height to base width ratio of more than 4:1 (including
outrigger supports, if used) will be restrained from tipping by guying, tying, bracing or
the equivalent, as follows:
a. Guys, ties and braces will be installed at locations where horizontal members
support both inner and other legs.
b. Guys, ties and braces will be installed in accordance with manufacturer's
recommendations or at the closest horizontal member to the 4:1 height and
repeated vertically every 20 feet or less for scaffolds less than 3 feet wide and
every 26 feet for scaffolds greater than 3 feet wide.
c. The top guy, tie or brace will be placed no further than the 4:1 height from the
top;
d. Guys, ties and braces will be installed at each end of the scaffold and at horizontal
intervals not to exceed 30 feet (measured from one end, not both, towards the
other end).
e. Ties, guys, braces or outriggers will be used to prevent the tipping of supported
scaffold where an eccentric load, such as a cantilevered work platform, is applied
or is transmitted to the scaffold.
2. Supported scaffold poles, legs, posts, frames and uprights will bear on base plates and
mudsills or other adequate firm foundations.
a. Footings will be level, sound, rigid and capable of supporting the loaded scaffold
without settling or displacement.
b. Unstable objects will not be used to support scaffolds or platforms, nor be used as
working platforms.
c. Front-end loaders and similar equipment will not be used to support scaffold
platform unless specifically designed by the manufacturer for such use.
d. Forklifts will not be used to support scaffold platforms unless the entire platform
is attached to the fork and the forklift is not moved horizontally while the
platform is occupied.
3. Supported scaffold poles, legs, posts, frames and uprights will be plumb and braced to
prevent swaying and displacement.
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Steingass Mechanical Contracting, Inc.
Supported Scaffold Inspection Record
Project:____________________________Date:_________________________ Competent person performing inspection:____________________________
Yes/No Action/Comments
1. Is guardrailing in place on all open . . sides and ends above 10 feet? . .
2. Are working level platforms fully . . planked between guardrails? . .
3. Are all plank free of warpage, damage . . or other defects and meets OSHA . . requirements? . .
4. Has proper access been provided? . .
5. Has scaffold been tied to the structure. . at intervals not exceeding 30’ . . horizontally and 26’ vertically? . .
6. Is the first tie at a height of 12 feet for . . 3 feet wide frames or 20 feet for 5 . . feet wide frames? . .
7. Are free ends of scaffold tied in at 9 . . feet for 3 feet wide frames or 15 feet . . for 5 feet wide frames? . .
8. Have freestanding towers been guyed . or tied every 20 feet in height for 5 . . feet wide frames? . .
9. Unsafe conditions and/or equipment, is tagged out and the foreman has been notified. . .
(See Attached Tag)
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CRITERIA FOR SUSPENSION SCAFFOLDS
1. Suspension support devices such as outrigger beams, cornice hooks, parapet clamps, and
similar devices shall rest on surfaces capable of supporting at least 4 times the load
imposed by the scaffold operating at the rated load of the hoist (or at least 1 times the
load imposed on them by the scaffold at the stall capacity of the hoist, whichever is
greater).
2. Suspension scaffold outrigger beams will be made of structural metal or material of
equivalent strength and be restrained to prevent movement.
3. The inboard ends of suspension scaffold outrigger beams will be stabilized by bolts or
other direct connections to the floor or roof deck; or stabilized by counterweights.
Masons' multi-point adjustable suspension scaffold outrigger beams will not be stabilized
by counterweights.
a. Before the scaffold is used, direct the competent person will evaluate connections
and confirm that the supporting surfaces are capable of supporting the loads. In
addition, an engineer experienced in scaffold design shall design mason’s multi-
point adjustable suspension scaffold connections.
b. Counterweights shall be made of non-flowable material. Sand, gravel and similar
materials shall not be used as counterweights.
c. Only items specifically designed for use as counterweights will be used.
Construction materials such as, but not limited to, masonry units, rolls of roofing
felts will not be used as counterweights.
d. Counterweights will be secured by mechanical means to the outrigger beams to
prevent displacement.
e. Counterweights will not be removed from the outrigger beam until the scaffold is
disassembled.
f. Outrigger beams not stabilized by bolts or other direct connections to the floor or
roof deck will be secured by tiebacks.
g. Tiebacks will be equivalent in strength to the suspension ropes.
h. Outrigger beams will be placed perpendicular to the bearing support. Where it is
not possible to place an outrigger beam perpendicular due to obstructions that
cannot be moved, the outrigger beam may be placed at some other angle
providing opposing angle tiebacks are used.
i. Tiebacks will be secured to a structurally sound anchorage on the building or
structure. Sound anchorages include structural members, but do not include
standpipes, vents, other piping systems or electrical conduit.
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j. Tiebacks will be installed perpendicular to the face of the building or structure, or
opposing angle tiebacks will be installed. Single tiebacks installed at an angle are
prohibited.
4. Suspension scaffold outrigger beams will be:
a. Provided with stop bolts or shackles at both ends;
b. Securely fastened together with the flanges turned out when channel iron beams
are used in place of I-beams;
c. Installed with all bearing supports perpendicular to the beam centerline;
d. Set and maintained with the web in a vertical position; and
e. The shackle or clevis with which the rope is attached to the outrigger beam will
be placed directly over the centerline of the stirrup.
5. Suspension scaffold support devices such as cornice hooks, roof hooks, roof irons,
parapet clamps or other similar devices will be:
a. Made of steel, wrought iron or materials of equivalent strength;
b. Supported by bearing blocks; and
c. Secured against movement with tiebacks installed at right angles to the face of the
building or structure, or opposing angle tiebacks will be installed and secured to a
structurally sound anchorage point on the building or structure.
d. Tiebacks will be equivalent in strength to the hoisting rope.
6. Winding drum hoists will contain not less than four wraps of the suspension rope at the
lowest point of scaffold travel. When other types of hoists are used, the suspension ropes
will be long enough to allow the scaffold to be lowered to the level below without the
rope end passing through the hoist or configured with means to prevent the end from
passing through the hoist.
7. The use of repaired wire rope as suspension rope is prohibited.
8. Wire suspension ropes will not be joined together except through the use of eye splice
thimbles connected with shackles or cover plates and bolts.
9. The load end of wire suspension ropes shall be equipped with proper size thimbles and
secured by eye splicing or the equivalent.
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10. Ropes will be inspected for defects by a competent person prior to each work shift and
after each occurrence, which could affect a rope's integrity. Ropes will be replaced when:
a. Any physical damage, which impairs the strength and function of the rope;
b. Kinks that may impair the tracking or wrapping of rope around the drums or
sheaves;
c. Six randomly distributed broken wires in one rope lay or three broken wires in
one strand in one rope lay;
d. Abrasion, corrosion, scrubbing, flattening or peening causing a loss of more than
1/3 of the original diameter of the outside wires;
e. Heat damage caused by a torch or damage caused by contact with electrical wires;
f. Evidence that the secondary brake has been activated during an overspeed
condition and has engaged the suspension rope.
11. Swaged attachments or spliced eyes on wire suspension ropes will not be used unless
they are made by the wire rope manufacturer or a qualified person.
12. When wire rope clips are used:
a. Minimum of 3 wire rope clips installed with the clips a minimum of 6 rope
diameters apart;
b. Clips will be installed according to manufacturer's recommendations;
c. Clips will be retightened to the manufacturer's recommendations after the initial
loading;
d. Clips will be inspected and retightened to the manufacturer's recommendations at
the start of each work shift thereafter;
e. U-bolt clips will be not be used at the point of suspension for any scaffold hoist;
f. When U-bolt clips are used, the U-bolt will be placed over the dead end of the
rope and the saddle will be placed over the live end of the rope.
13. Suspension scaffold power-operated hoists and manual hoists will be tested by a qualified
testing laboratory.
14. Gasoline-powered equipment and hoists will be not used on suspension scaffolds.
15. Gears and brakes of power-operated hoists used on suspension scaffolds will be enclosed.
16. Suspension scaffold power-operated hoists and manually operated hoists will have a
braking device or locking pawl which engages automatically when a hoist makes either
an instantaneous change in momentum or an accelerated overspeed in addition to the
normal operating brake.
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17. Manually operated hoists will require a positive crank force to descend.
18. Two-point and multi-point suspension scaffolds will be tied or otherwise secured to
prevent them from swaying as determined by an evaluation of a competent person.
Window cleaner's anchors will be not be used.
19. Devices whose sole function is to provide emergency escape and rescue will not be used
as working platforms.
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ACCESS 1. When scaffold platforms are more than 2 feet above or below a point of access, portable
ladders, hook-on ladders, attachable ladders, stair towers, stairway-type ladders, ramps,
walkways, integral prefabricated scaffold access or direct access from another scaffold,
structure or personnel hoist will be used. Cross braces will not be used as a means of
access.
2. Portable, hook-on and attachable ladders will:
a. Be positioned so as not to tip the scaffold;
b. Hook-on and attachable ladders will be positioned so that their bottom rung is not
more than 24 inches above the scaffolding supporting level;
c. Hook-on and attachable ladders used on a supported scaffold more than 35 feet
high, they shall have rest platforms at 35-foot maximum vertical intervals;
d. Hook-on and attachable ladders will be specifically designed for use with the type
of scaffold used;
e. Hook-on and attachable ladders will have a minimum rung length of 11 inches;
and
f. Hook-on and attachable ladders will have rungs uniformly spaced with a
maximum spacing between rungs of 16 inches.
3. Stairway-type ladders will:
a. Positioned so that the bottom step is not more than 24 inches above the scaffold
supporting level;
b. Provided with rest platforms at 12-foot maximum vertical intervals;
c. Minimum step width of 16 inches. Mobile scaffold stairway-type ladders will
have a minimum step width of 11 inches; and
d. Steps and landings will have slip-resistant treads.
4. Stairtowers (scaffold stairway/towers) will be positioned so that the bottom step is not
more than 24 inches above the scaffold supporting level.
a. A stairrail consisting of a toprail and midrail will be provided on each side of each
scaffold stairway.
b. The toprail will be capable of serving as a handrail, unless a separate handrail is
provided.
c. Handrails (and toprails used as handrails) will provide an adequate handhold for
employees grasping them to avoid falling.
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d. Stairrail systems and handrails will be surfaced to prevent injury from punctures
or laceration and to prevent snagging of clothing.
e. The ends of stairrail systems and handrails will be constructed so that they do not
constitute a projection hazard.
f. Handrails (and toprails used as handrails) will be at least 3 inches from other
objects.
g. Stairrails will be not less than 28 inches nor more than 37 inches from the upper
surface of the stairrail to the surface of the tread, in line with the face of the riser
at the forward edge of the tread.
h. A landing platform at least 18 inches wide by at least 18 inches long will be
provided at each level.
i. Each scaffold stairway will be at least 18 inches wide between stairrails.
j. Treads and landing will have slip-resistant surfaces.
k. Stairways will be installed between 40 degrees and 60 degrees from the
horizontal.
l. Guardrails will be provided on the open sides and ends of each landing.
m. Riser height will be uniform, within inch, for each flight of stairs. The top and
bottom steps of the entire system are allowed greater variations.
n. Tread depth will be uniform, within inch, for each flight of stairs.
5. Ramps and walkways:
a. Six feet or more above lower levels will have guardrails;
b. Will not be inclined more than a slope of one (1) vertical to three (3) horizontal
(20 degrees above the horizontal).
c. With a slope steeper than one vertical to eight horizontal will have cleats not more
than fourteen inches apart securely fastened to the planks to provide footing.
6. Integral prefabricated scaffold access frames will:
a. Be designed and constructed for use as ladder rungs;
b. Have a rung length of at least 8 inches;
c. Not be used as work platforms when rungs are less than 11 inches in length
unless each employee uses fall protection or a positioning device;
d. Be uniformly spaced within each frame section;
e. Be provided with rest platforms at 35 feet maximum vertical intervals on all
supported scaffolds more than 35 feet high; and
f. Have a maximum spacing between rungs of 16 inches. Non-uniform rung
spacing caused by joining end frames together is permitted, providing the spacing
does not exceed 16 inches.
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7. Steps and rungs of ladder and stairway type access will line up vertically with each other
between rest platforms.
8. Direct access to or from another surface will be used only when the scaffold is not more
than 14 inches horizontally and not more than 24 inches vertically from the other surface.
9. Access for employees erecting or dismantling supported scaffolds will in accordance with
the following:
a. Steingass Mechanical Contracting, Inc. will provide a safe means of access for
each employee erecting and dismantling a scaffold where it is feasible and does
not create a greater hazard. A competent person will determine whether it is
feasible or poses a greater hazard based on site conditions and the type of scaffold
being erected or dismantled.
b. Hook-on or attachable ladders will be installed as soon as scaffold erection has
progressed to a point that permits safe installation and use.
c. When erecting or dismantling tubular welded frame scaffolds, end frames, with
horizontal members that are parallel, level and are not more than 22 inches apart
vertically may be used as climbing devices for access providing they are erected
in a manner that creates a usable ladder and provides good hand hold and foot
space.
d. Cross braces on tubular welded frame scaffold will not be used as a means of
access or egress.
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FALLING OBJECT PROTECTION
1. Each employee on a scaffold will be provided with additional protection from falling
hand tools, debris and other small objects through the installation of toeboards, screens or
guardrail systems or through the erection of debris nets, catch platforms or canopy
structures that either contain or deflect the falling objects. Employees are required to
wear hardhats.
a. When the falling objects are too large, heavy or massive to be contained or
deflected by the above listed measures, such potential falling objects will be
placed away from the edge and materials secured to prevent their falling.
2. When the danger of tools, materials or equipment falling from a scaffold and striking
employees below the following provisions will be met:
a. The area below the scaffold will be barricaded and employees will not be
permitted to enter the hazard area; or
b. A toeboard will be erected along the edge of platforms more than 10 feet above
lower levels for a distance sufficient to protect employees below. On float
scaffolds, an edging of x 1 inch wood or the equivalent may be used instead of
toeboards;
c. Where tools, materials or equipment are piled higher than the top edge of the
toeboard, panels or screens extending from the toeboard or platform to the top of
the guardrail will be erected for a distance sufficient to protect employees below;
or
d. A guardrail system will be installed with openings small enough to prevent
objects from falling; or
e. A canopy structure, debris net or catch platform strong enough to withstand the
impact of potential falling objects will be erected over the employees below.
3. Canopies, when used for falling object protection will comply with the following:
a. Canopies will be installed between the falling object hazard and employees.
b. When canopies are used on suspension scaffolds for falling object protection, the
scaffold will be equipped with additional independent support lines equal in
number to the number of points supported and equivalent in strength to the
strength of the suspension ropes.
c. Independent support lines and suspension ropes will not be attached to the same
points of anchorage.
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4. Toeboards, when used, will be:
a. Capable of withstanding, without failure, a force of at least 50 pounds applied in
any downward or horizontal direction at any point along the toeboard; and
b. At least 3 inches high from the top edge of the toeboard to the level of the
walking/working surface.
c. Toeboards will be securely fastened in place at the outermost edge of the platform
with not more than 1/4 inch clearance above the walking/working surface.
d. Toeboards will be solid or with openings not over 1 inch in its greatest dimension.
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USE
1. Scaffolds and scaffold components will not be loaded in excess of their maximum
intended load or rated capacity, whichever is less.
2. The use of shore or lean-to scaffolds is prohibited.
3. Scaffolds and scaffold components will be inspected for visible defects by a competent
person before each work shift, periodically, and after any occurrence, which could affect
the scaffold's structural integrity. Unsafe equipment or conditions will be tagged out by
competent persons and must be complied with. (Examples of tagging out systems are
attached.)
4. Any part of a scaffold damaged or weakened will be immediately repaired or replaced,
braced or removed from service until repaired.
5. Scaffolds will not be moved horizontally while employees are on them unless designed
by a registered profession engineer specifically for such movement or for mobile
scaffolds.
6. Scaffolds will not be erected, used, dismantled, altered or moved so that they or any
conductive material handled on them might come closer to exposed and energized power
lines than as follows:
a. Insulated lines:
i. Less than 300 volts, minimum distance between lines and any part of
scaffold or materials will be 3 feet;
ii. 300 volts to 50 kv, minimum distance between lines and any part of
scaffold or materials will be 10 feet;
iii. More than 50 kv, minimum distance between lines and any part of
scaffold or materials will be 10 feet plus .4 inches for each 1 kv over 50
kv.
b. Uninsulated lines:
i. Less than 50 kv, minimum distance between lines and any part of scaffold
or materials will be 10 feet;
ii. More than 50 kv, minimum distance between lines and any part of
scaffold or materials will be 10 feet plus .4 inches for each 1 kv over 50
kv.
c. Exception: Scaffolds and materials may be closer to power lines than specified
above where such clearance is necessary for performance of work only after the
lines have been de-energized, relocated or installed with protective coverings to
prevent accidental contact with the lines.
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7. Scaffolds will be erected, moved, dismantled or altered only under the supervision and
direction of the competent person. Only experienced and trained employees selected by
the competent person will perform such activities.
8. Employees are prohibited from working on scaffolds covered with snow, ice or other
slippery material except as necessary for removal.
9. Where swinging loads are being hoisted onto or near scaffolds where the load may
contact the scaffold, tag lines will be utilized to control the load.
10. Suspension ropes supporting adjustable suspension scaffolds will be of a diameter large
enough to provide sufficient surface area for the functioning of brake and hoist
mechanisms.
11. Suspension ropes will be shielded from heat-producing processes. When acids or other
corrosive substances are used on scaffolds, the ropes will be shielded, treated or be of a
material that will not be damaged by the substance being used.
12. Work on or from scaffolds is prohibited during storms or high winds unless a competent
person has determined that it is safe for employees and those employees are protected by
a personal fall arrest system or wind screen. Windscreens will not be used unless the
scaffold is secured against the anticipated wind forces imposed.
13. Debris will not be allowed to accumulate on platforms.
14. Boxes, barrels and other makeshift devices will not be used on top of scaffold platforms
to increase the working level height of employees.
15. Ladders will not be used on scaffolds to increase the working level height of employees,
except on large area scaffolds where the following criteria has been met:
a. When the ladder is placed against a structure, which is not a part of the scaffold,
the scaffold will be secured against the sideways thrust exerted by the ladder;
b. The platform units will be secured to the scaffold to prevent their movement;
c. The ladder legs will be on the same platform to stabilize the ladder against
unequal platform deflection, and
d. The ladder legs will be secured to prevent them from slipping or being pushed off
the platform.
16. Platforms shall not deflect more than 1/60 of the span when loaded.
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17. To reduce the possibility of welding current arcing through the suspension wire rope
when performing welding from suspended scaffolds, the following precautions will be
taken, as applicable:
a. An insulated thimble will be used to attach each suspension wire rope to its
hanging support. Excess suspension wire rope and any additional independent
lines from grounding will be insulated;
b. The suspension wire rope will be covered with insulating material extending at
least 4 feet above the hoist. If there is a tail line below the hoist, it will be
insulated to prevent contact with the platform. The portion of the tail line that
hangs free below the scaffold will be guided or retained, or both, so that it does
not become grounded;
c. Each hoist will be covered with insulated protective covers;
d. A grounding conductor will be connected from the scaffold to the structure in
addition to a work lead attachment. The size of this conductor will be at least the
size of the welding process work lead and this conductor will not be in series with
the welding process or the work piece;
e. If the scaffold grounding lead is disconnected at any time, the welding machine
will be shut off; and
f. An active welding rod or uninsulated welding lead will not be allowed to contact
the scaffold or its suspension system.
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FALL PROTECTION
1. Each employee on a scaffold more than 10 feet above a lower level will be protected
from falling to that lower level.
a. Each employee on a boatswains' chair, catenary scaffold, float scaffold, needle
beam scaffold or ladder jack scaffold will be protected by a personal fall arrest
system;
b. Each employee on a single-point or two-point adjustable suspension scaffold will
be protected by both a personal fall arrest system and guardrail system;
c. Each employee on a crawling board will be protected by a personal fall arrest
system, a guardrail system or by a inch diameter grabline or equivalent handhold
securely fastened beside each crawling board;
d. Each employee on a self-contained adjustable scaffold will be protected by a
guardrail system when the platform is supported by the frame structure and by
both a personal fall arrest system and a guardrail system when ropes suspend the
platform;
e. Each employee on a walkway located within a scaffold will be protected by a
guardrail system installed within 9 inches of and along at least one side of the
walkway.
f. Each employee performing overhand bricklaying operations from a supported
scaffold will be protected from falling from all open sides and ends of the scaffold
(except at the side next to the wall being laid) by the use of a personal fall arrest
system or guardrail system.
g. For all other scaffolds, each employee will be protected by the use of personal fall
arrest system or guardrail systems.
2. Steingass Mechanical Contracting, Inc. will determine the feasibility and safety of
providing fall protection for employees erecting and dismantling supported scaffolds.
Fall protection will be provided for employees erecting and dismantling supported
scaffolds where installation and use of fall protection is feasible and does not create a
greater hazard.
3. Personal fall arrest system used on scaffolds will be attached by lanyard to a vertical
lifeline, horizontal lifeline or scaffold structural member. Vertical lifelines will not be
used when overhead components such as overhead protection or additional platform
levels are part of a single-point or two-point adjustable suspension scaffold.
a. Vertical lifelines will be fastened to a fixed safe point of anchorage, independent
of the scaffold and protected from sharp edges and abrasion. Safe points of
anchorage include structural member of buildings, but do not include standpipes,
vents, other piping systems, electrical conduit outrigger beams or counterweights.
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b. Horizontal lifelines will be secured to two or more structural members of the
scaffold or looped around both suspension and independent suspension lines
above the hoist and brake attached to the end of the scaffold. Horizontal lifelines
will not be attached only to the suspension ropes.
c. When lanyards are connected to horizontal lifelines or structural members on
single-point or two-point adjustable suspension scaffold, the scaffold will be
equipped with additional independent support lines and automatic locking devices
capable of stopping the fall of the scaffold in the event one or both suspension
ropes fail. The independent support lines will be equal in number and strength to
the suspension ropes.
d. Vertical lifelines, independent support lines and suspension ropes will not be
attached to each other nor attached to or use the same anchorage point on the
scaffold or personal fall arrest systems.
4. Guardrail systems installed will comply with the following:
a. Guardrail systems will be installed along all open sides and ends of platforms.
Guardrail systems will be installed before employees other than
erection/dismantling crews release the scaffold for use.
b. The top edge height of toprails or equivalent member on supported scaffold will
be installed between 38 inches and 45 inches.
c. Midrails, screens, mesh; intermediate vertical members, and solid panels will be
installed between the top edge of the guardrail system and the scaffold platform.
d. When midrails are used, they will be installed at a height approximately midway
between the top edge of the guardrail system and the platform surface.
e. When screens and mesh are used, they will extend from the top edge of the
guardrail system to the scaffold platform and along the entire opening between the
supports.
f. When intermediate members, i.e. balusters, additional rails, are used, they will not
be more than 19 inches apart.
g. Each toprail (or equivalent member) of a guardrail system will be capable of
withstanding, without failure, a force applied in any downward or horizontal
direction at any point along its top edge at least 100 pounds for guardrail systems
installed on single-point adjustable suspension scaffolds or two-point adjustable
suspension scaffolds and at least 200 pounds for guardrail systems installed on all
other scaffolds.
h. When loads are applied to toprails in a downward direction, the top edge will not
drop below 36 inches (before January 1, 2000) or 38 inches
(after January 1, 2000).
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i. Midrails, screens, mesh, intermediate vertical members, solid panels and
equivalent structural members of a guardrail system will be capable of
withstanding, without failure, a force applied in any downward or horizontal
direction at any point along the midrail or other member of at least 75 pounds for
guardrail systems with a minimum 100 pound toprail capacity and at least 150
pounds for guardrail systems with a minimum 200 pound toprail capacity.
j. Suspension scaffold hoists and non-walk-through stirrups may be used as end
guardrails if the space between the hoist or stirrup and the side guardrail or
structure does not allow passage of an employee to the end of the scaffold.
k. Guardrails will be surfaced to prevent injury to an employee from punctures or
lacerations and to prevent snagging of clothing.
l. The ends of all rails will not overhand the terminal posts except when the
overhang does not constitute a project hazard to employees.
m. Steel or plastic banding will not be used as a toprail or midrail.
n. Manila or plastic or other synthetic rope being used for toprails or midrails will be
inspected by the competent person as frequently as necessary to ensure that it
continues to meet the strength requirements.
o. Cross bracing is acceptable in place of a midrail when the crossing point of two
braces is between 20 inches and 30 inches above the work platform.
Cross bracing is acceptable in place of a toprail when the crossing point of
two braces is between 38 inches and 48 inches above the work platform.
The end points at each upright shall be no more than 48 inches apart.
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CRITERIA FOR SPECIFIC TYPES OF SCAFFOLD
1. Pole Scaffolds.
a. When platforms are being moved to the next level, the existing platform will be
left undisturbed until the new bearers have been set in place and braced before
placing the new platforms.
b. Cross bracing will be installed between the inner and outer sets of poles on
double-pole scaffolds.
c. Diagonal bracing in both directions will be installed across the entire inside face
of double-pole scaffolds used to support loads equivalent to a uniformly
distributed load of 50 pounds or more per square foot.
d. Diagonal bracing in both directions will be installed across the entire outside face
of all double- and single-pole scaffolds.
e. Runners and bearers will be installed on the edge.
f. Bearers will extend a minimum of 3 inches over the outside edges of runners.
g. Runners will extend over a minimum of two poles and will be supported by
bearing blocks securely attached to the poles.
h. Braces, bearers and runners will not be spliced between poles.
i. Where wooden poles are spliced, ends will be squared and the upper section will
rest squarely on the lower section. Wood splice plates will be provided on at least
two adjacent sides and will extend at least 2 feet on either side of the splice,
overlap the abutted ends equally and have at least the same cross-sectional areas
as the pole. Splice plates of other materials of equivalent strength may be used.
j. Pole scaffolds over 60 feet in height will be designed by a registered professional
engineer and will be constructed and loaded in accordance with that design.
2. Tube and coupler scaffolds.
a. When platforms are being moved to the next level, the existing platform will be
left undisturbed until the new bearers have been set in place and braced prior to
placing the new platforms.
b. Transverse bracing forming an "X" across the width of the scaffold will be
installed at the scaffold ends and at least at every third set of posts horizontally
(measured from only one end) and every fourth runner vertically. Bracing will
extend diagonally from the inner or outer posts or runners upward to the next
outer or inner posts or runners. Building ties will be installed at the bearer levels
between the transverse bracing.
c. On straight run scaffolds, longitudinal bracing across the inner and outer rows of
posts will be installed diagonally in both directions and will extend from the base
of the end posts upward to the top of the scaffold at approximately a 45-degree
angle.
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i. On scaffolds whose length is greater than their height, the bracing will be
repeated beginning at least at every fifth post.
ii. On scaffolds who length is less than their height, the bracing will be
installed from the base of the end posts upward to the opposite end posts
and then in alternating directions until reaching the top of the scaffold.
iii. Bracing will be installed as close as possible to the intersection of the
bearer and post or runner and post.
d. Where conditions do not allow attachment of bracing to posts, bracing will be
attached to the runners as close to the post as possible.
e. Bearers will be installed transversely between posts and when coupled to the
posts, will have the inboard coupler bear directly on the runner coupler. When the
bearers are coupled to the runners, the couplers will be as close to the posts as
possible.
f. Bearers will extend beyond the posts and runners and will provide full contact
with the coupler.
g. Runners will be installed along the length of the scaffold, located on both the
inside and outside posts at level heights. When tube and coupler guardrails and
midrails are used on outside posts, they may be used instead of outside runners.
h. Runners will be interlocked on straight runs to form continuous lengths and will
be coupled to each post. The bottom runners and bearers will be located as close
to the base as possible.
i. Couplers will be of a structural metal, i.e. drop-forged steel, malleable iron or
structural grade aluminum. The use of gray cast iron is prohibited.
j. Tube and coupler scaffolds over 125 feet in height will be designed by a
registered professional engineer and be constructed and loaded in accordance with
the design.
3. Fabricated frame scaffolds (tubular welded frame scaffolds).
a. When moving platforms to the next level, the existing platform will be left
undisturbed until the new end frames have been set in place and braced prior to
placing the new platforms.
b. Frames and panels will be braced by cross, horizontal, or diagonal braces or a
combination, which secure vertical members together laterally. The cross braces
will be of a length to automatically square and align vertical members so the
erected scaffold is always plumb, level and square. All brace connections will be
secured.
c. Frames and panels will be joined together vertically by coupling or stacking pins.
d. Where uplift can occur, the end frames or panels will be locked together vertically
by pins.
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e. Brackets used to support cantilevered loads will:
i. Be seated with side-brackets parallel to the frames and end-brackets at 90
degrees to the frames;
ii. Not be bent or twisted from these positions; and
iii. Be used only to support personnel, unless the scaffold has been designed
for other loads by a qualified engineer and built to withstand the tipping
forces caused by those other loads being placed on the bracket-supported
section.
f. Scaffolds over 125 feet in height above their base plates will be designed by a
registered professional engineer and will be constructed and loaded in accordance
with the design.
4. Plasterers', decorators' and large area scaffolds.
Scaffolds will be constructed as outlined in the section “Criteria for Specific Types of
Scaffolds”, “Pole scaffolds”, “Tube and coupler scaffolds” and “ Fabricated frame
scaffolds.”
5. Bricklayers' square scaffolds.
a. Scaffolds made of wood will be reinforced with gussets on both sides of each
corner.
b. Diagonal braces will be installed on all sides of each square.
c. Diagonal braces will be installed between squares on the rear and front sides of
the scaffold and will extend from the bottom of each square to the top of the next
square.
d. Scaffolds will not exceed three tiers in height and will be so constructed and
arranged that one square rest directly above the other. The upper tiers will stand
on a continuous row of planks laid across the next lower tier and will be nailed
down or otherwise secured to prevent displacement.
6. Horse scaffolds.
a. Scaffolds will not be constructed or arranged more than two tiers or 10 feet in
height, whichever is less.
b. When horses are arranged in tiers, each horse will be placed directly over the
horse in the tier below.
c. When horses are arranged in tiers, the legs of each horse will be nailed down or
otherwise secured to prevent displacement.
c. When horses are arranged in tiers, each tier will be crossbraced.
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7. Form scaffolds and carpenters' bracket scaffolds.
a.. Each bracket, except those for wooden bracket-form scaffolds, will be attached to
the supporting formwork or structure by means of one or more of the following:
i. nails;
ii. a metal stud attachment device;
iii. welding;
iv. hooking over a secured structural supporting member, with the form wales
either bolted to the form or secured by snap ties or tie bolts extending
through the form and securely anchored;
v. for carpenters' bracket scaffolds only, by a bolt extending through to the
opposite side of the structure's wall.
b. Wooden bracket-form scaffolds will be an integral part of the form panel.
c. Folding type metal brackets, when extended for use, will be either bolted or
secured with a locking-type pin.
8. Roof bracket scaffolds.
a. Scaffold brackets will be constructed to fit the pitch of the roof and will provide a
level support for the platform.
b. Brackets will be anchored in place by nails unless it is impractical use nails.
When nails are not used, brackets will be secured in place with first-grade manila
rope of at least 3/4-inch diameter or its equivalent.
9. Outrigger scaffolds.
a. The inboard end of the outrigger beams, measured from the fulcrum point to the
extreme point of anchorage, will not be less than 1½ times the outboard end in
length.
b. Outrigger beams fabricated in the shape of an I-beam or channel will be placed so
that the web section is vertical.
c. The fulcrum point of outrigger beams will rest on secure bearings at least 6 inches
in each horizontal dimension.
d. Outrigger beams will be secured in place against movement and will be securely
braced at the fulcrum point against tipping.
e. The inboard ends of outrigger beams will be securely anchored either by means of
braced struts bearing against sills in contact with the overhead beams or ceiling or
with tension members secured to the floor joists underfoot or by both.
f. The entire supporting structure will be securely braced to prevent any horizontal
movement.
g. To prevent their displacement, platform units will be nailed, bolted or otherwise
secured to outriggers.
h. Scaffolds and scaffold components will be designed by a registered professional
engineer and will be constructed and loaded in accordance with the design.
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10. Pump jack scaffolds.
a. Pump jack brackets, braces and accessories will be fabricated from metal plates
and angles. Each pump jack bracket will have two positive gripping mechanisms
to prevent any failure or slippage.
b. Poles will be secured to the structure by rigid triangular bracing or equivalent at
the bottom, top and other points as necessary. When the pump jack has to pass
bracing already installed, an additional brace will be installed approximately 4
feet above the brace to be passed and will be lift in place until the pump jack has
been moved and the original brace installed.
c. When guardrails are used for fall protection, a workbench may be used as the
toprail.
d. Work benches will not be used a scaffold platforms.
e. When wood poles are made of wood, the pole lumber will be straight-grained,
free of shakes, large loose or dead knots and other defects, which might impair
strength.
f. When poles are constructed of two continuous lengths, they will be joined
together with the seam parallel to the bracket.
g. When two by fours are spliced to make a pole, mending plates will be installed at
all splices to develop the full strength of the member.
11. Ladder jack scaffolds.
a. Platforms will not exceed a height of 20 feet.
b. Job-made ladders will not be used to support ladder jack scaffolds.
c. The ladder jack will be so designed and constructed that it will bear on the side
rails and ladder rungs or on the ladder rungs alone. If bearing on rungs only, the
bearing area will include a length of at least 10 inches on each rung.
d. Ladders used to support ladder jacks will be placed, fastened or equipped with
devices to prevent slipping.
e. Scaffold platforms will not be bridged one to another.
12. Window jack scaffolds.
a. Scaffolds will be securely attached to the window opening.
b. Scaffolds will be used only for the purpose of working at the window opening
through which the jack is placed.
c. Window jacks will not be used to support planks placed between one window
jack and another or for other elements of scaffolding.
13. Crawling boards (chicken ladders).
a. Crawling boards will extend from the roof peak to the eaves when used in
connection with roof construction, repair or maintenance.
b. Crawling boards will be secured to the roof by ridge hooks or the equivalent.
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14. Step, platform, and trestle ladder scaffolds.
a. Scaffold platforms will not be placed any higher than the second highest rung or
step of the ladder supporting the platform.
b. Job-made ladders will not be used to support step, platform and trestle ladder
scaffolds.
c. Ladders used to support step, platform and trestle ladder scaffolds will be placed,
fastened or equipped with devices to prevent slipping.
d. Scaffolds will not be bridged one to another.
15. Single-point adjustable suspension scaffolds.
a. When two single-point adjustable suspension scaffolds are combined to form a
two-point adjustable suspension scaffold, the resulting two-point scaffold will
comply with the requirements as outlined in the “Criteria for Specific Types of
Scaffolds - Two-Point Adjustable Suspension Scaffold”
b. The supporting rope between the scaffold and the suspension device will be kept
vertical unless the following conditions are met:
i. The rigging has been designed by a qualified person, and
ii. The scaffold is accessible to rescuers, and
iii. The supporting rope is protected to ensure that it will not chafe at any
point where a change in direction occurs, and
iv. The scaffold is positioned so that swinging cannot bring the scaffold into
contact with another surface.
c. Boatswains' chair tackle will consist of correct size ball bearings or bushed blocks
containing safety hooks and properly "eye-spliced" minimum 5/8-inch diameter
first-grade manila rope or its equivalent.
d. Boatswains' chair seat slings will be reeved through four corner holes in the seat;
will cross each other on the underside of the seat; and will be rigged to prevent
slippage, which could cause an out-of-level condition.
e. Boatswains' chair seat slings will be a minimum of 5/8-inch diameter fiber,
synthetic or other rope with the equivalent strength, slip resistance, durability of
first-grade manila rope.
f. When a heat-producing process, i.e. gas or arc welding, is being conducted,
boatswains' chair seat slings will be a minimum of 3/8-inch wire rope.
g. Non-cross-laminated wood boatswains' chairs will be reinforced on their
underside by cleats securely fastened to prevent the board from splitting.
16. Two-point adjustable suspension scaffolds (swing stages).
a. Platforms will not be more than 36 inches wide unless designed by a qualified
person to prevent unstable conditions.
b. The platform will be securely fastened to hangers (stirrups) by U-bolts or their
equivalent.
c. The blocks for fiber or synthetic ropes will consist of at least one double and one
single block. The sheaves of all blocks will fit the size of rope used.
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d. Platforms will be of the ladder-type, plank-type, beam-type, or light-metal type.
Light metal-type platforms having a rated capacity of 750 pounds or less and
platforms 40 feet or less in length will be tested and listed by a nationally
recognized testing laboratory.
e. Two-point scaffolds will not be bridged or otherwise connected one to another
during raising and lowering operations unless the bridge connections are attached
and the hoists properly sized.
f. Passage may be made from one platform to another only when the platforms are
at the same height, are abutting and equipped with walk-through stirrups designed
for this purpose.
17. Multi-point adjustable suspension scaffolds, stonesetters' multi-point adjustable
suspension scaffolds and masons' multi-point adjustable suspension scaffolds.
a. When two or more scaffolds are used they will not be bridge one to another unless
they are designed to be bridged, the bridge connections are attached and the hoists
are properly sized.
b. If bridges are not used, passage may be made from one platform to another only
when the platforms are at the same height and abutting.
c. Scaffolds will be suspended from metal outriggers, brackets, wire rope slings,
hooks or their equivalent.
18. Catenary scaffolds.
a. No more than one platform will be placed between consecutive vertical pickups,
and no more than two platforms will be used on a catenary scaffold.
b. Platforms supported by wire ropes will have hook-shaped stops on each end of the
platforms to prevent them from slipping off the wire ropes. These hooks will be
placed so they will prevent the platform from falling if one of the horizontal wire
ropes breaks.
c. Wire ropes will not be tightened to the extent that the application of the scaffold
load will overstress them.
d. Wire ropes will be continuous and without splices between anchors.
19. Float (ship) scaffolds.
a. The platform will be supported by a minimum of two bearers, each of which will
project a minimum of 6 inches beyond the platform on both sides. Each bearer
will be securely fastened to the platform.
b. Rope connections will be such that the platform cannot shift or slip.
c. When only two ropes are used with each float:
i. They will be arranged to provide four ends, which are securely fastened to
overhead supports.
ii. Each supporting rope will be hitched around one end of the bearer and
pass under the platform to the other end of the bearer where it is hitched
again, leaving sufficient rope at each end for the supporting ties.
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20. Interior hung scaffolds.
a. Scaffolds will be suspended only from the roof structure or other structural
member such as ceiling beams.
b. Overhead supporting members (roof structure, ceiling beams or other structural
members) will be inspected and checked for strength before the scaffold is
erected.
c. Suspension ropes and cables will be connected to the overhead supporting
members by shackles, clips, thimbles or their equivalent.
21. Needle beam scaffolds.
a. Scaffold support beams will be installed on edge.
b. Ropes or hangers will be used for supports, except that one end of a needle beam
a permanent structural member may support scaffold.
c. The ropes will be securely attached to the needle beams.
d. The support connection will be arranged to prevent the needle beam from rolling
or becoming displaced.
e. Platform units will be securely attached to the needle beams by bolts or the
equivalent. Cleats and overhang are not considered to be adequate means of
attachment.
22. Multi-level suspended scaffolds.
a. Scaffolds will be equipped with additional independent support lines, equal in
number to the number of points supported and of equivalent strength to the
suspension ropes and rigged to support the scaffold in the event the suspension
rope(s) fail.
b. Independent support lines and suspension ropes will not be attached to the same
points of anchorage.
c. Supports for platforms will be attached directly to the support stirrup and not to
any other platform.
23. Mobile scaffolds.
a. Scaffolds will be braced by cross, horizontal or diagonal braces or combinations
to prevent racking or collapse of the scaffold and to secure vertical members
together laterally to automatically square and align the vertical members.
Scaffolds will be plumb, level and squared. All brace connections will be
secured.
i. Scaffolds constructed of tube and coupler components will comply with
the requirements as outlined in “Criteria for Specific Types of Scaffolds -
Tube and Coupler Scaffolds”
ii. Scaffolds constructed of fabricated frame components will comply with
the requirements as outlined in “Criteria for Specific Types of Scaffolds -
Fabricated Frame Scaffolds”
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b. Scaffold casters and wheels will be locked with positive wheel and/or wheel and
swivel locks to prevent movement of the scaffold while the scaffold is used in a
stationary manner.
c. Manual force used to move the scaffold will be applied as close to the base but
not more than 5 feet above the supporting surface.
d. Power systems used to propel mobile scaffolds will be designed for such use.
Forklift, trucks, similar motor vehicles or add-on motors will be not be used to
propel scaffolds.
e. Scaffolds will be stabilized to prevent tipping during movement.
f. Employees will not be allowed to ride on scaffolds unless the following
conditions exist:
i. The surface on which the scaffold is being moved is within 3 degrees of
level and free of pits, holes and obstructions;
ii. The height to base width ratio of the scaffold during movement is 2:1 or
less.
iii. Outrigger frames are installed on both sides of the scaffold;
iv. When power systems are used, the force is applied directly to the wheels
and does not produce a speed in excess of 1 foot per second; and
v. No employee is on any part of the scaffold, which extends outward
beyond the wheels, casters or other supports.
g. Platforms will not extend outward beyond the base supports of the scaffold unless
outrigger frames or equivalent devices are used to ensure stability.
h. Where leveling of the scaffold is necessary, screw jacks will be used.
i. Caster stems and wheel stems will be pinned in scaffold legs or adjustment
screws.
j. Before a scaffold is moved, each employee on the scaffold will be made aware of
the move.
24. Repair bracket scaffolds.
a. Brackets will be secured by at least one wire rope at least 1/2 inch in diameter.
b. Each bracket will be attached to the securing wire rope(s) by a positive locking
device capable of preventing the unintentional detachment of the bracket from the
rope.
c. Each bracket at the contact point between the supporting structure and the bottom
of the bracket will be provided with a shoe (heel block or foot) capable of
preventing the lateral movement of the bracket.
d. Platforms will be secured to the brackets so as to prevent the separation of the
platforms from the brackets and the movement of the platforms or the brackets on
a completed scaffold.
e. When a wire rope is placed around the structure in order to provide a safe
anchorage for personal fall arrest systems used by employees erecting or
dismantling scaffolds, the wire rope will be at least 5/16 inch in diameter.
43
f. Each wire rope used for securing brackets in place or as an anchorage for personal
fall arrest systems will be protected from damage due to contact with edges,
corners, protrusions of the supporting structure or scaffold components.
g. Tensioning of each wire rope used for securing brackets in place or as an
anchorage for personal fall arrest systems will be by means of a turnbuckle at
least 1 inch in diameter or the equivalent.
h. Each turnbuckle will be connected to the other end of its rope by use of an
eyesplice thimble of a size appropriate to the turnbuckle.
i. U-bolt wire rope clips will not be used on any wire rope used to secure brackets or
to serve as an anchor for personal fall arrest systems.
j. Steingass Mechanical Contracting, Inc. will ensure that materials will not be
dropped to the outside of the supporting structure.
k. Scaffold erection will progress in only one direction around any structure.
25. Stilts
a. An employee may wear stilts on a scaffold only if it is a large area scaffold.
b. When an employee is using stilts where a guardrail is used to provide fall
protection, the guardrail system will be increased in height by an amount equal to
the height of the stilts being used by the employee.
c. Surfaces on which stilts are used will be flat and free of pits, holes and
obstructions such as debris, and other tripping hazards.
d. Stilts will be properly maintained. The manufacturer will approve alterations of
the original equipment.
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45
46
47
48
49
AERIAL LIFTS
Aerial lifts acquired for use on or after January 22, 1973 will be designed and constructed in
conformance with ANSI A92.2-1969, including appendix. Aerial lift acquired before January
22, 1973, which do not meet, the requirements of ANSI A92.2-1969 are prohibited from use
unless they have been modified to conform to the design and construction requirements of ANSI
A92.2-1969.
Aerial lifts include the following types of vehicle-mounted aerial devices used to elevate
personnel to job sites above ground:
Extensible boom platforms;
Aerial ladders;
Articulating boom platforms;
Vertical towers; and
A combination of any such devices.
Aerial equipment may be made of metal, wood, fiberglass reinforced plastic (FRP); may be
powered or manually operated; and are deemed to be aerial lifts whether or not they are capable
of rotating about a substantially vertical axis.
Aerial lifts “field modified” for uses other than those intended by the manufacturer, must be
approved by the manufacturer (or any other equivalent entity such as a nationally recognized
laboratory) conform with all applicable provisions of ANSI A92.2-1969 and to be at least as safe
as the equipment was before modification.
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SPECIFIC REQUIREMENTS FOR AERIAL LIFTS
1. Ladder trucks and tower trucks.
a. Aerial ladders will be secured in the lower traveling position by the locking
device on top of the truck cab and the manually operated device at the base of the
ladder before the truck is moved for highway travel.
2. Extensible and articulating boom platforms.
a. Lift controls will be tested each day prior to use to determine that the controls are in
safe working condition.
b. Authorized personnel only will operate an aerial lift.
c. Belting off to an adjacent pole, structure or equipment while working from an aerial
lift is prohibited.
d. Employees will always stand firmly on the floor of the basket and will not sit or climb
on the edge of the basket or use planks, ladders or other devices for a work platform.
e. A body belt will be worn and a lanyard attached to the boom or basket when working
from an aerial lift. Note: Body belts are not acceptable as part of a personal fall
arrest system; however, the use of a body belt as a positioning device is acceptable.
f. Boom and basket load limits specified by the manufacturer will not be exceeded.
g. The brakes will be set and when outriggers are used, they will be positioned on pads
or a solid surface. Wheel chocks will be install before using an aerial lift on an
incline, provided they can be safety installed.
h. An aerial lift truck will not be moved when the boom is elevated in a working
position, except for equipment specifically designed for this type of operation.
i. Articulating boom and extensible boom platforms, primarily designed as personnel
carriers, will have bother platform (upper) and lower controls. Upper controls will be
in or beside the platform within easy reach of the operator. Lower controls will
provide for overriding the upper controls. Controls will be plainly marked as to their
function. Lower level controls will not be operated unless permission has been
obtained from the employee in the lift, except in the case of emergency.
j. Climbers will not be worn while performing work from an aerial lift.
k. The insulated portion of an aerial lift will not be altered in any manner that might
reduce its insulating value.
l. Before moving an aerial lift for travel, the boom(s) will be inspected to see that it is
properly cradled and outriggers are in stowed position.
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3. Electrical tests.
a. All electrical tests will conform to the requirements of ANSI A92.2-1969 (section
5). However, equivalent DC voltage tests may be used instead of the AC voltage
specified in A92.2-1969. DC voltage tests, which the equipment manufacturer
approves, or equivalent entity will be considered an equivalent test.
4. Bursting safety factor.
a. The provision of ANSI A92.2-1969, section 4.9 Bursting Safety Factor, will apply
to all critical hydraulic and pneumatic components. Critical components are those
in which a failure would result in a free fall or free rotation of the boom. All non-
critical components will have a bursting safety factor of at least 2:1.
5. Welding standards.
a. All welding will conform to the following standards as applicable:
i. Standard Qualification Procedure, AWS B3.0-41.
ii. Recommended Practices for Automotive Welding Design, AWS D8.4-61.
iii. Standard Qualification of Welding Procedures and Welders for Piping and
Tubing, AWS D10.9-69.
iv. Specifications for Welding Highway and Railway Bridges, AWS D2.0-69.
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Employee Training and Information
Steingass Mechanical Contracting, Inc. will instruct all applicable employees whose scope of
work is covered or intended to be covered by Subpart L regarding the hazards by a qualified
person.
Consequently, the standard for the safe use of scaffolding deals with both the human and
equipment related issues in protecting employees from the hazards associated with the use of
scaffolds.
It is the intent that by training these employees in Steingass Mechanical Contracting, Inc.’s
Scaffold Program, that we will eliminate hazards including falls, electrical, falling objects, use,
load capacity and mandatory tagging system.
Retraining will be conducted for any employee at any time that an affected employee who has
already been trained does not demonstrate the requisite understanding or skill required, anytime
conditions change, or when new equipment is introduced.
Competent person training as outlined by the CFR 1926 Subpart L and annual refresher training
shall be provided for jobsite superintendents on any jobsite that the scope of work requires
scaffolding.
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Steingass Mechanical Contracting, Inc.
Subpart “L” - Scaffolds
Employee Name: ______________________________________________________________
Test Date: ____________________________________________________________________
1. Scaffolds and scaffold components will support times the maximum intended load.
a. 1
b. 2
c. 4
d. 6
2. Scaffolds more than 3 feet wide will be secured to the structure at intervals of feet
vertically and feet horizontally.
a. 20, 24
b. 22, 26
c. 26, 30
d. 10, 20
3. Platforms used, as walkway will be at least ______ inches wide.
a. 9
b. 12
c. 36
d. 18
4. Which of the following conditions require that suspension rope used on suspension
scaffolds be replaced?
a. Six broken wires in one rope lay exist.
b. Kinks that impair the tracking of rope around the drum or sheave.
c. Heat or electrical damage.
d. All of the above.
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Subpart “L” - Scaffolds
Page Two
5. Guardrails will be installed on open sides and ends of walkways more than above a
lower level.
a. 10
b. 8
c. 6
d. 16
6. will be used to control hoisted swinging loads to prevent loads from contacting
the scaffold.
a. Signals
b. Tag lines
c. Wind
d. Hands
7. Steel banding may be used as toprail or midrails.
a. True b. False
8. Rest platforms must be provided on all supported scaffolds more than 35 feet high.
a. True b. False
9. On mobile scaffolds, at least two f the four wheels must be locked to prevent movement.
a. True b. False
10. Which of the following situations is a cause of scaffold overloads?
a. Scaffold base is placed on unstable ground.
b. Scaffold planks are cracked or damaged.
c. Scaffold loads are not spread out evenly across the whole platform.
d. All of the above.
11. Unsafe scaffold conditions (circle all that apply):
a. Scaffold not level and plumb
b. Use of unstable objects to support the scaffold
c. Scaffold planking overhanging too far
d. Missing crossbraces.
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Subpart “L” - Scaffolds
Page Three
12. When U-bolt clips are used on wire rope, the U-bolt will be placed over the live end of
the rope and the saddle placed over the dead end of the rope.
a. True b. False
13. List four acceptable scaffold access systems:
a.
b.
c.
d.
14. Employees are permitted to ride on mobile scaffolds when the following conditions exist:
a. The surface is within 3 degrees of level and free of pits, holes and
obstructions.
b. The height to base ratio is 2:1 or less.
c. Outrigger frames, when used, are installed on both sides of the scaffold.
d. All of the above.
15. On tubular welded frame scaffold, cross braces are required on every other section of
scaffolding.
a. True b. False
16. If a ramp is steeper than 1 vertical to 8 horizontal, then cleats will be fastened to the
planks 14 inches apart to improve footing.
a. True b. False
17. On a scaffold system utilizing screw jacks, the scaffold become stable as the
wing nut is screwed higher.
a. Less b. More
18. Concrete blocks or brick are acceptable for use as mudsills.
a. True b. False
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Subpart “L” - Scaffolds
Page Four
19. When ascending or descending a ladder, employees must:
a. Not carry anything heavier than ½ their body weight.
b. Grasp the ladder with both hands.
c. Face the ladder, hold on with at least one hand and not carry anything that
may cause them to fall.
d. Hold on with both hands only if the ladder is being shifted or moved.
20. The anchorages for personal fall arrest systems may be doubled up with the anchorages
for suspension scaffolds.
a. True b. False
Training conducted by:
Training date:
57
Steingass Mechanical Contracting, Inc.
Fall Protection Check List for Erection / Dismantling
Steingass Mechanical Contracting, Inc. supports the use of conventional fall protection when it is
clearly beneficial to the erectors. This checklist was designed to help our lead man in
determining the feasibility of using conventional fall protection systems.
Project Name:
Project Location:
Prepared By: Date:
(Circle “YES” or “NO”)
YES NO 1. Is the scaffolding system being built next to a structure? [24” maximum
distance from the building and structure must be as tall or taller than the
top of the building]
YES NO 2. Is the scaffold short in length? [two bays maximum so that there is no
pendulum effect on the lifelines]
YES NO 3. Is there an adequate anchorage point for the lifelines? [5,000 lbs.Capacity
for each life line]
YES NO 4. Is there safe access to the anchorage point?
NOTE: If you answered all the above questions with a “YES” then you must use conventional
fall protection on this project. If you answered “NO” to any of the questions then you must
complete and implement the Steingass Mechanical Contracting, Inc. Erection / Dismantle Fall
Protection Plan on this project and attach this check list to the plan.
58
Steingass Mechanical Contracting, Inc.
Erection / Dismantle Fall Protection Plan
The following Fall Protection Plan is a program prepared for the prevention of injuries associated
with falls.
Project Name:
Project Location:
Date Plan Prepared (or modified):
Plan Prepared By:
Plan Approved By:
Plan Supervised By:
Steingass Mechanical Contracting, Inc. is dedicated to the protection of its employees from on-
the-job injuries. All employees of Steingass Mechanical Contracting, Inc. have the responsibility
to work safely on the job. The purpose of this plan is to supplement our existing safety and
health program and to ensure that every employee recognizes workplace fall hazards and takes
the appropriate measures to address those hazards.
This Fall Protection Plan supports the use of conventional fall protection when it is clearly
beneficial to the erector. During the erection / dismantling of scaffolds, it is often unfeasible or a
creates a greater hazard to use conventional fall protection systems during the different phases,
which include, but are not limited to:
a. Setting and bracing of scaffold frames and other components;
b. Installation of planking and deck sheathing.
In those cases, which would create a greater hazard for the erectors, conventional fall protection
systems must be not be used. This plan is designed to enable the erectors to recognize the fall
hazards associated with this project and to establish the safest procedures that are to be followed
in order to reduce those hazards and prevent falls.
59
ERECTION / DISMANTLE FALL PROTECTION PLAN
Page 2 of 7
Each employee will be trained in these procedures and will strictly adhere to them except when
doing so would expose the employee to a greater hazard. If in the employee’s opinion, this is the
case, the employee is to notify the competent person of their concern and have the concern
addressed before proceeding.
It is the responsibility of Steingass Mechanical Contracting, Inc. to implement this Fall
Protection Plan. Continual observational safety checks of work operations and the enforcement
of the safety policy and procedures will be regularly enforced.
The crew supervisor or foreman: _______________________________________ is
responsible for correcting any unsafe practices or conditions immediately.
It is the responsibility of Steingass Mechanical Contracting, Inc. to ensure that all employees
understand and adhere to the procedures of this plan and to follow the instructions of the
foreman. It is also the responsibility of the employee to bring to management’s attention any
unsafe or hazardous conditions or practices that may cause injury to either themselves or any
other employees. Any changes to the Fall Protection Plan must be approved by:
______________________________.
Name/Title
FALL PROTECTION SYSTEMS TO BE USED ON THIS JOB
Installation of scaffold frames, cross bracing, planking, decking and all other scaffold
components will be conducted by employees who are specifically trained to do this type of work
and are trained to recognize the fall hazards. The nature of such work normally exposes the
employee to the fall hazards. This Fall Protection Plan details how Steingass Mechanical
Contracting, Inc. will minimize these hazards.
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ERECTION / DISMANTLE FALL PROTECTION PLAN
Page 3 of 7
CONTROLLED ACCESS ZONES
When utilizing this plan to implement the fall protection options available, employees
must be protected through limited access to high hazard locations. Before any non-
conventional fall protection systems are used as part of the work plan, a controlled access
zone (CAZ) will be clearly defined by the competent person as an area where a
recognized hazard exists.
The competent person will communicate the demarcation of the CAZ in a recognized
manner, either through signs, types, ropes or chains. Steingass Mechanical Contracting,
Inc. will take the following steps to ensure that the CAZ is clearly marked or controlled
by the competent person:
All access to the CAZ must be restricted to authorized entrants;
All employees who are permitted in the CAZ will be listed in the appropriate
sections of the Plan and be visibly identifiable by the competent person prior
to implementation;
The competent person will ensure that all protective elements of the CAZ be
implemented prior to the beginning of work.
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ERECTION / DISMANTLE FALL PROTECTION PLAN
Page 4 of 7
INSTALLATION PROCEDURES FOR THE SCAFFOLD FRAMES,
CROSS BRACES, PLANKS, DECKING AND ALL
OTHER SCAFFOLD COMPONENTS
Conventional fall protection may present a greater hazard to employees. On this job, the
use of personal fall arrest systems will not provide adequate fall protection because there
are no anchorage points for personal fall arrest systems. On this job, requiring the
erectors to attach their personal fall arrest systems to the scaffolding below them will
create a tripping hazard. In addition, the scaffold does not provide an adequate anchorage
point (5,000 lbs.) and requiring the erectors to attach to the scaffold will give them a false
sense of security.
Steingass Mechanical Contracting, Inc. will take the following steps to protect erectors
who are exposed to fall hazards while working from the scaffold frames and the
incomplete work platforms:
Only the following trained employees will be allowed to work on the
incomplete scaffold system installation:
Employees will have no other duties to perform during scaffold erection
procedures;
the entire scaffold frames will be adequately braced before any worker can use
them as a support;
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ERECTION / DISMANTLE FALL PROTECTION PLAN
Page 5 of 7
Employees will remain on the previously stabilized scaffold frames / planks as
a support while the other frames / planks are being erected;
Erectors will leave the area of the secured frames only when it is necessary to
secure another frame;
Once scaffold erection installation beings, employees not involved in that
activity will not stand or walk below or adjacent to the scaffold system being
erected or in any area where they could be struck of falling objects;
Employees will not remain on the scaffold system longer than necessary to
safely complete the task.
When strong winds (above 40 miles per hour) are present, erection operations
of frames, bracing, planks and all other components are to be suspended.
DECK SHEATHING INSTALLATION OPERATIONS
Employees typically install the frames, all the joists and required bracing before the
sheathing is installed. To minimize the time erectors must be exposed to a fall hazard,
materials will be staged to allow for the quickest installation of sheathing.
Steingass Mechanical Contracting, Inc. will take the following steps to protect employees
who are exposed to fall hazards while installing deck sheathing:
Only the following trained employees will be allowed to work on the
incomplete scaffold system installation:
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ERECTION / DISMANTLE FALL PROTECTION PLAN
Page 6 of 7
Once deck sheathing installation beings, employees not involved in that
activity will not stand or walk below or adjacent to the scaffold system or
in any area where they could be struck by falling objects;
The competent person will determine the limits of this area, which will be
clearly communicated to employees prior to placement of the first piece of
deck sheathing;
The competent person may order work on the deck to be suspended for
brief periods as necessary to allow other employees to pass through such
areas when this would not create a greater hazard;
Any employees not assisting in the leading edge construction while
leading edges still exist (i.e. cutting the decking for the installers) will not
be permitted within six feet of the leading edge under construction.
Materials for operations will be conveniently staged to minimize fall
hazards;
When wet weather (rain, snow or sleet) is present, deck sheathing
operations will be suspended unless safe footing can be assured for those
employees installing sheathing.
When strong winds (above 40 miles per hour) are present, deck sheathing
operations are to be suspended.
ENFORCEMENT
Constant awareness of and respect for fall hazards and compliance with all safety rules are
considered conditions of employment. The foreman has the total authority to stop the progress
of the project until all unsafe conditions have been corrected. Management reserves the right to
issue disciplinary warnings to employees, up to and including termination, for failure to follow
the guidelines of this program.
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ERECTION / DISMANTLE FALL PROTECTION PLAN
Page 7 of 7
ACCIDENT INVESTIGATIONS
All accidents that result in injury to employees, regardless of their nature, will be reported and
investigated. It is an integral part of any safety program that documentation takes place as soon
as possible so that the cause and means of prevention can be identified to prevent a recurrence.
In the event that an employee falls and there is some other related, serious incident occurring,
this Plan will be reviewed to determine if additional practices, procedures or training need to be
implemented to prevent similar types of falls or incidents from occurring.
CHANGES TO PLAN
Any changes to the plan will be approved by _________________________________________
Name/Title
A qualified person will review this plan as the job progresses to determine if additional practices,
procedures or training needs to be implemented by the competent person to improve additional
fall protection. Employees will be notified and trained, if necessary, in the new procedures. A
copy of this plan and all approved changes will be posted at the job site.