Scaffolding is a
temporary frame used to support people and material in the construction or
building and other large structures. It is usually a modular system of metal
pieced although it can be made out of other materials. The purpose of a working
scaffold is to provide a safe place of work with safe access suitable for the
work being done. This document sets out performance requirements for working
scaffolds. These are substantially independent of the materials of which the
scaffold is made. The standard is intended to be used as the basis for enquiry
and design .The basic materials are tubes, couplers and boards.
Basic scaffolding
The key elements of a scaffold are standards,
ledgers and transoms. The standards, also called uprights, are the vertical
tubes that transfer the entire mass of the structure to the ground where they
rest on a square base plate to spread the load. The base plate has a shank in
its centre to hold the tube and is sometimes pinned to a sole board. Ledgers
are horizontal tubes which connect between the standards. Transoms rest upon
the ledgers at right angles. Main transoms are placed next to the standards, they
hold the standards in place and provide support for boards; intermediate
transoms are those placed between the main transoms to provide extra support
for boards. In Canada this style is referred to as "English".
"American" has the transoms attached to the standards and is used
less but has certain advantages in some situations. Since scaffolding is a
physical structure, it is possible to go in and come out of scaffolding. As
well as the tubes at right angles there are crossbraces to increase
rigidity, these are placed diagonally from ledger to ledger, next to the
standards to which they are fitted. If the braces are fitted to the ledgers
they are called ledger braces. To limit sway a facade brace is fitted to the
face of the scaffold every 30 metres or so at an angle of 35°-55° running right
from the base to the top of the scaffold and fixed at every level. Of the
couplers previously mentioned, right-angle couplers join ledgers or transoms to
standards, putlog or single couplers join board bearing transoms to ledgers -
Non-board bearing transoms should be fixed using a right-angle coupler. Swivel
couplers are to connect tubes at any other angle. The actual joints are
staggered to avoid occurring at the same level in neighbouring standards. Basic
scaffold dimensioning terms. No boards, bracing or couplers shown The spacing
of the basic elements in the scaffold are fairly standard. For a general
purpose scaffold the maximum bay length is 2.1 m, for heavier work the bay size
is reduced to 2 or even 1.8 m while for inspection a bay width of up to 2.7 m
is allowed. The scaffolding width is determined by the width of the boards, the
minimum width allowed is 600 mm but a more typical four-board
scaffold would be 870 mm wide from standard to standard. More heavy duty scaffolding
can require 5, 6 or even up to 8 boards width. Often an inside board is added
to reduce the gap between the inner standard and the structure. The lift
height, the spacing between ledgers, is 2 m, although the base lift can be up
to 2.7 m. The diagram above also shows a kicker lift, which is just 150 mm or
so above the ground. Transom spacing is determined by the thickness of the
boards supported, 38 mm boards require a transom spacing of no more than 1.2 m
while a 50 mm board can stand a transom spacing of 2.6 m and 63 mm boards can
have a maximum span of 3.25 m. The minimum overhang for all boards is 50 mm and
the maximum overhang is no more than 4x the thickness of the board. Scaffolding
in Foundations Good foundations are essential. Often scaffold frameworks will
require more than simple base plates to safely carry and spread the load.
Scaffolding can be used without base plates on concrete or similar hard
surfaces, although base plates are always recommended. For surfaces like
pavements or tarmac base plates are necessary. For softer or more doubtful
surfaces sole boards must be used, beneath a single standard a sole board
should be at least 1,000 cm2 with no dimension less than 220
mm, the thickness must be at least 35 mm. For heavier duty scaffold much more
substantial baulks set in concrete can be required. On uneven ground steps must
be cut for the base plates, a minimum step size of around 450 mm is
recommended. A working platform requires certain other elements to be safe.
They must be close-boarded, have double guard rails and toe and stop boards.
Safe and secure access must also be provided. Scaffolds are only rarely
independent structures. To provide stability for a scaffolding (at left)
framework ties are generally fixed to the adjacent building / fabric /
steelwork. General practice is to attach a tie every 4m on alternate lifts
(traditional scaffolding) prefabricated System scaffolds require structural
connections at all frames - ie.2-3m centres (tie patterns must be provided by
the System manufacturer / supplier). The ties are coupled to the scaffold as
close to the junction of standard and ledger (node point) as possible. Due to
recent regulation changes, scaffolding ties must support +/- loads (tie/butt
loads) and lateral (shear) loads. Due to the different nature of structures
there are a variety of different ties to take advantage of the opportunities.
Through ties are put through structure openings such as windows. A vertical
inside tube crossing the opening is attached to the scaffold by a transom and a
crossing horizontal tube on the outside called a bridle tube. The gaps between
the tubes and the structure surfaces are packed or wedged with timber sections
to ensure a solid fit. Box ties are used to attach the scaffold to suitable
pillars or comparable features. Two additional transoms are put across from the
lift on each side of the feature and are joined on both sides with shorter
tubes called tie tubes. When a complete box tie is impossible a l-shaped lip
tie can be used to hook the scaffold to the structure, to limit inward movement
an additional transom, a butt transom, is place hard against the outside face
of the structure. Sometimes it is possible to use anchor ties (also called bolt
ties), these are ties fitted into holes drilled in the structure. A common type
is a ring bolt with an expanding wedge which is then tied to a node point. The
least 'invasive' tie is a reveal tie. These use an opening in the structure but
use a tube wedged horizontally in the opening. The reveal tube is usually held
in place by a reveal screw pin (an adjustable threaded bar) and protective
packing at either end. A transom tie tube links the reveal tube to the
scaffold. Reveal ties are not well regarded, they rely solely on friction and
need regular checking so it is not recommended that more than half of all ties
be reveal ties. If it is not possible to use a safe number of ties rakers can
be used. These are single tubes attached to a ledger extending out from the
scaffold at an angle of less than 75° and securely founded. A transom at the
base then completes a triangle back to the base of the main scaffold. Putlog
scaffold As well as putlog couplers there are also putlog tubes, these have a
flattened end or have been fitted with a blade. This feature allows the end of
the tube to be within or rest upon the brickwork of the structure. They can be
called a bricklayer's scaffold and as such consist only of a single row of
standards with a single ledger, the putlogs are transoms - attached to the ledger
at one end but integrated into the bricks at the other. Spacing is as general
purpose scaffold and ties are still required.
Formwork
comes in three main types:
1.Traditional
timber formwork. : -
The form work is built on site out of timber and ply wood or moisture
resistant particle board.It is easy to produce but time-consuming for larger
structures, and the plywood facing has a relatively short lifespan. It is still
used extensively where the labor costs are lower than the costs for procuring
re-usable formwork. It is also the most flexible type of formwork, so even
where other systems are in use, complicated sections may use it.
2.Engineered Formwork Systems:
This formwork is built out of prefabricated modules with a metal frame
(usually steel or aluminium.) and covered on the application (concreted side
with material having the wanted surface structure (steel, aluminium, timber,
etc.). The two major advantages of formwork systems, compared to traditional
timber formwork, are speed of construction (modular systems pin, clip, or screw
together quickly) and lower life-cycle costs (barring major force, the frame is
almost indestructible, while the covering if made of wood; may have to be
replaced after a few - or a few dozen - uses, but if the covering is made with
steel or aluminum the form can achieve up to two thousand uses depending on
care and the applications).
3. Re-usable plastic formwork:
These interlocking and modular systems are used to build widely
variable, but relatively simple, concrete structures. The panels are
lightweight and very robust. They are especially suited for low-cost, mass
housing schemes Stay-In-Place formwork systems. This formwork is assembled on
site, usually out of prefabricated insulating formwork. The formwork stays in
place (or is simply covered with earth in case of buried structures) after the
concrete has cured, and may provide thermal and acoustic insulation, space to
run utilities within, or backing for finishes. Stay-In-Place structural formwork
systems. These are in the shape of hollow tubes, and are usually used for
columns and piers. Slab formwork (deck formwork) Some of the earliest
examples of concrete slabs were built by
Roman engineers. Because concrete is quite strong in resisting
compressive load, but has relatively poor tensile or torsional strength, these
early structures consisted of arches,vaultsanddomes. To mold these
structure, temporary scaffolding and formwork was built in the future shape of
the structure. .Timber beam slab formwork Similar to the traditional
method, but stringers and joist are replaced with engineered wood beams and
supports are replaced with metal props. This makes this method more systematic
and reusable. Traditional slab formwork Traditional timber formwork On
the dawn of the rival of concrete in slab structures, building techniques for
the temporary structures were derived again from masonry and carpentry. The
traditional slab formwork technique consists of supports out of lumber or young
tree trunks, that support rows of stringers assembled roughly 3 to 6 feet or 1
to 2 meters apart, depending on thickness of slab. Between these stringers,
joists are positioned roughly 12 inches, 30 centimeters apart upon which boards
or plywood are placed. The stringers and joists are usually 4 by 4 inch or 4 by
6 inch lumber. The most common imperial plywood thickness is 3A inch
and the most common metric thickness is 21 millimeters. Metal Beam Slab
Formwork Similar to the traditional method, but stringers and joist are
replaced with aluminium forming systems or steel beams and supports are
replaced with metal props. This also makes this method more systematic and
reusable. Hand setting modular aluminum deck formwork. Handset modular aluminum
formwork.Modular Slab Formwork These systems consist of prefabricated
timber, steel or aluminum beams and formwork modules. Modules are often no
larger than 3 to 6 feet or 1 to 2 meters in size. The beams and formwork are
typically set by hand and pinned, clipped, or screwed together. The advantages
of a modular system are: does not require a crane to place the formwork, speed
of construction with unskilled labor, formwork modules can be removed after
concrete sets leaving only beams in place prior to achieving design
strength. Table or flying form systems These systems consist of slab
formwork "tables" that are reused on multiple stories of a building
without being dismantled. The assembled sections are either lifted per elevator
or "flown" by crane from one story to the next. Once in position the
gaps between the tables or table and wall are filled with "fillers".
They vary in shape and size as well as their building material. The use of
these systems can greatly reduce the time and manual labor involved in setting
and striking the formwork. Their advantages are best utilized by large area and
simple structures. It is also common for architects and engineers to design
building around one of these systems.Structure A table is built much the
same way as a beam formwork but the single parts of this system are
connected together in a way that makes them transportable. The most common
sheathing is plywood, but steel and fiberglass are also in use. The joists are
either made from timber, wood I-beams, aluminium or steel. The Stringers are
sometimes made of wood I-beams but usually from steel channels. These are
fastened together (screwed, weld or bolted) to become a "deck". These
decks are usually rectangular but can also be other shapes.Support All
support systems have to be height adjustable to allow the formwork to be placed
at the correct height and to be removed after the concrete is cured. Normally
adjustable metal props similar to (or the same as) those used by beam slab
formwork are used to support these systems. Some systems combine stringers and
supports into steel or aluminium trusses. Yet other systems use metal frame
shoring towers, which the decks are attached to. Another common method is to
attach the formwork decks to previously cast walls or columns, thus eradicating
the use of vertical props altogether. In this method, adjustable support shoes
are bolted through holes (sometimes tie holes) or attached to cast anchors.
Size The size of these tables can vary from 70 sqft. to 1500 sqft. or 8 m2 to
150 m2. There are two general approaches in this system.
· Crane
handled: this approach consists of assembling or producing the tables with
a large formwork area that can only be moved up a level by crane. Typical
widths can be 15, 18 or 20ft. or 5 to 7 meters but their width can be limited,
so that it is possible to transport them assembled, without having to pay for
an oversize load. The length vary and can be up to 100ft. (or more) depending
on the crane capacity. After the concrete is cured, the decks are lowered and
moved with rollers or trolleys to the edge of the building. From then on the
protruding side of the table is lifted by crane whiles the rest of the table is
rolled out of the building. After the center of gravity is outside of the
building the table reattached to another crane and flown to the next level or
position.
This technique is fairly
common in the United States and east Asian countries. The advantages of this
approach are the further reduction of manual labor time and cost per area of
slab and a simple and systematic building technique. The disadvantages of this
approach are the necessary high lifting capacity of building site cranes,
additional expensive crane time, higher material costs and little flexibility.
· Crane
fork or elevator handled:
By this approach the tables are limited in size and weight. Typical
widths are between 6 to 10 ft or 2 to 3 meters, typical lengths are between 12
and 20ft or 4 to 7 meters, though table sizes may vary in size and form. The
major distinction of this approach is that the tables are lifted either with a
crane transport fork or by material platform elevators attached to the side of
the building. They are usually transported horizontally to the elevator or
crane lifting platform single handedly with shifting trolleys depending on
their size and construction. Final positioning adjustments can be made by
trolley. This technique enjoys popularity in the US, Europe and generally in
high labor cost countries. The advantages of this approach in comparison to
beam formwork or modular formwork is a further reduction of labor time and
cost. Smaller tables are generally easier to customize around geometrically
complicated buildings, (round or non rectangular) or to form around
columns in comparison to their large counterparts. The disadvantages of this
approach are the higher material costs and increased crane time (if lifted with
crane fork).
Usage
For removable forms, once the concrete has been poured into formwork and
has set (or cured), the formwork is struck or stripped (removed) to expose the
finished concrete. The time between pouring and formwork stripping depends on
the job specifications, the cure required, and whether the form is supporting
any weight, but is usually at least 24 hours after the pour is completed. For
example, the California Department of Transportation requires the
forms to be in place for 1-7 days after pouring, while the Washington State
Department of Transportation requires the forms to stay in place for 3 days
with a damp blanket on the outside.
Spectacular accidents have occurred when the forms were either removed
too soon or had been under-designed to carry the load imposed by the weight of
the uncured concrete. Less critical and much more common (though no less
embarrassing and often costly) are those cases in which underdesigned formwork
bends or breaks during the filling process (especially if filled with a
high-pressure concrete pump). This then results in fresh concrete escaping
out of the formwork in a form blowout, often in large quantities.
Concrete exerts less
pressure against the forms as it hardens, so forms are usually designed to
withstand a number of feet per hour of pour rate to give the concrete at the
bottom time to firm up.
The hardening is an asymptotic process, meaning that most of the final
strength will be achieved after a r short time, though some further hardening
can occur depending on the cement type andadmixtures.
Wet concrete also applies hydrostatic pressure to formwork. The pressure
at the bottom of the form is therefore greater than at the top. In the
illustration of the column formwork to the right, the 'column clamps' are
closer together at the bottom. Note that the column is braced with steel
adjustable 'formwork props' and uses 20 mm 'through bolts' to further support
the long side of the column.
