Scaffolding is a temporary structure installed against the side of a building, around a chimney, etc. to provide platforms for workers and materials during construction, maintenance, etc. Although there are many varieties of scaffolding systems, a common one is called independenttube and coupling scaffolding – popular because it transports efficiently, erects intuitively, and breaks down easily. Other scaffolding designs are used inside facilities for worker access to overhead equipment, for painting, etc. These designs are usually limited in height but have other features such as the ability to fold or telescope. Still, other scaffolds are available for specialized tasks such as building aircraft.
Scaffolding must adhere to OSHA standards for performance requirements and structural design methods. Because scaffolding must be compatible with a wide array of buildings and structures, there are numerous kinds of scaffolds to meet specific building requirements. However, scaffolding generally comprises some basic elements, though the manner in which they are designed and the way such elements fit together can vary.
1. Base plate
2. Sole plate
3. Standards
4. Ledgers
5. Transoms
6. Bracing
8. Platform/Decking
9. Clamps standard: EN-74 and BS-15.
10.Toe board should be minimum 6 inches in height.
11. Guard rails (Hand rails and mid-rails) height approximately 1 meter.
12. Working platform
13. Ties
14.The ladder shall be secure at three locations.
15.Tags either green or red tag and shall be renewed after one week.
A flat supportingplate or frame at thebase of a column, designed to distribute the column's weight over a greater area and provide increased stability.
Scaffold Base Plate is a footplate forscaffold systems of Ring lockScaffolding, Kwik stageScaffolding, Cup lockScaffolding,Scaffolding Frames, Tube and ClampScaffold. SocketBase Plate is used to as Socket of Universal Jacks,Scaffold Poles.Base Plate is Mainly Used to Spread The Load Onto The SolePlates.
All uprights or standards of ascaffold are to be mounted on a steel base plate. The thickness of the steel base plate shall be a minimum 6mm and size shall be of 150 mm x 150mm. Irrespective of the supporting ground condition or concrete surface, the base plate is to be used mandatory.
Thepurpose of the mud sill under the scaffold base plate is to uniformly distribute thescaffold load over a larger area than that distributed by thebase plate alone, thereby reducing the loading on the groundbeneath thebase plates.
Types of Base Plate
A minimumthickness of 12 mm is recommended for posts and lightly loaded columns, while 20 mm minimumthickness is recommended for normal applications Preferredplate thicknesses for thebase plate are: 12, 16, 20, 25, 28, 32, 36, 40.Base plates are typically cut to size using thermal processes.
A timber spreader used to distribute the load from a baseplate to the ground. Tie Scaffold components installed to provide an anchor point for ascaffold to a building or structure, including tie tubes attached to thescaffold. Used to provide lateral stability to thescaffold.
Thesole plate, also sometimes referred to as thesill plate, the mudsill, or the baseplate, is the main supporting beam of a wall in the construction industry. Typically, these are the first piece of wood that is in contact with the masonry of the basement or foundation.
A timber or metal barrier to distributing the load from a standard or base plate to the ground and prevents the sinking of the scaffold. The width and thickness of a timber sole plate shall be 200mm and 25 mm minimum. In place of timber soleplate, 10 mm thick steel plate or steel channel of size more than 200mm depth (ISMC 200) with flanges facing upward, may also be used as the soleplate.
The soleplate area shall not be less than sq.cm. Sole plates should be long enough to hold at least two vertical pipes and should extend 600 mm beyond the vertical pipes. Sole plates may be avoided in case the scaffold is erected on the firm ground like the concrete floor.
BASE PLATE / JACKS - to safely carry and spread the load. A metalplate with a spigot for distributing the load from a standard or raker or other load-bearing tube.
SOLE PLATES - A timber, concrete or metal bearer used to distribute the load from a standard orbase plate to the ground.
A standard is the long pipe or tube running vertically that connects the mass of the scaffold directly to the ground. The base of each standard is connected to a base plate, or sill, which helps distribute the weight each standard bears. As standards are of fixed lengths, taller scaffolding requires that the pipes be connected so as to route the load directly through the structure. This is accomplished by way of a pin and socket joint which twists to lock successive pipes together.
Pairs of standards are placed at the back of the scaffolding (nearest the building) and at the front of the scaffold, the two pairs of standards forming a bay that has a width (back-to-front dimension) and length (side-to-side dimension).
The standards, also called uprights, are the vertical tubes that transfer the entire weight of the structure to the ground where they rest on a square base plate to spread the load.
Tubes are usually made either of steel or aluminum; although there is composite scaffolding which uses filament-wound tubes of glass fiber in a nylon or polyester matrix, because of the high cost of composite tube, it is usually only used when there is a risk from overhead electric cables that cannot be isolated. If steel, they are either 'black' or galvanized. The tubes come in a variety of lengths and a standard outside diameter of 48.3 mm. (1.5 NPS pipe). The chief difference between the two types of metal tubes is the lower weight of aluminum tubes (1.7 kg/m as opposed to 4.4 kg/m). However they are more flexible and have a lower resistance to stress. Tubes are generally bought in 6.3 m lengths and can then be cut down to certain typical sizes. Most large companies will brand their tubes with their name and address in order to deter theft.
Galvanized steel scaffold tube is the main scaffolding part which creates the framework and the base for working platforms. Scaffold tubes are made from galvanized steel, are heavy duty and come in various lengths ranging from 5ft to 21ft and all have a different part to play.
In general 21 foot or 6.4 meter tubes are used as the upright standards and these are one of the main components that connects most of the scaffolding together. Standards are placed in a vertical position from the ground up on to a baseplate which is a scaffolding part that helps spread the weight.
For general scaffolding works e.g. painting and decorating, each upright standard should be placed a maximum of 2 meters apart. For heavy duty works where there is a heavy load going to be placed on the working platform then the standards should be a very maximum distance of 1.8 meters apart and this is generally called the bay length.
If you are looking to erect scaffolds higher than 21ft then the standards would need to be connected on top of one another using a joint pin scaffolding part which is inserted into the inner tube which then locks the uprights together.
To create a scaffolding bay you would need the following scaffolding parts, two pairs of standards, one should be close to the building and is usually referred to as the inside standard or upright. The next standards would be placed directly opposite the inside uprights and are usually called the outside standards which then creates the bay. The width and length dimensions of each bay may vary depending on what types of scaffold you require.
Thickness of tubes: measure the inside wall and regardless of the length most galvanized tube measures in at 4mm in thickness.
Scaffolding tubes diameter: you need to measure the outside of the tube from edge to edge. You will find most type 4 tubes no matter what length they are have a diameter which is usually 48.3mm or 1.90 inches.
STANDARD-DIFFERENT TYPE OF DAMAGES
The galvanizing process: is pretty simple, when the poles are manufactured the metal is sealed from all corrosion and oxidation. The steel poles are hot dipped in to a bath of molten zinc at temperatures exceeding 800 degrees Fahrenheit adding a bonded coating to the steel for extra protection.
These poles have been put through the galvanizing process to ensure that they are environmentally friendly and also strong and hard wearing, resistant to rust and have an increased life span. Buying steel scaffold tube is slightly more expensive than other poles available and this is due to the galvanizing, however you will save your money in the long run as these steel tubes will require far less maintenance or replacing.
Every Scaffold and every member or component thereof shall be:
In between each standard, running horizontally along the length of the scaffold, is a ledger or runner or cross beam, which adds further support and weight distribution. Multiple bays are connected with these ledgers both at the back and the front of the scaffold. Placement of ledgers defines the height at which the worker platforms are staged (except for the lowest one which is placed near the ground).
Joints in ledgers should also be staggered, i.e. joints in adjacent ledgers should not occur in the same bay. These joints should be made with sleeve couplers and not be more than one-third distance away from a points in ledgers on the same lift and in adjacent lifts should not occur in the same bay unless there is unjointed guardrail (not to be removed) when joints in the ledgers above and below can be in the same bay.
The spacing of ledgers (lift heights) will be:
independent tied scaffolds – 2.0m
putlog scaffolds – 1.35m
Some types of system scaffold do not require ledger/cross bracing unless:
Where ledger bracing is installed for the above reasons, the loads on the adjacent ties will be increased. The system manufacturer’s instructions should be consulted to determine whether ledger bracing is required.
Ledger bracing should be installed on tube and fitting scaffolds. Brace alternate pairs of tube and fitting standards, ensuring that the bracing forms a complete series of triangles from bottom to top of the scaffold. Install the bracing from ledger to ledger or from standard to standard. For tube and fitting scaffolds, brace each pair of standards where the bracing is installed from the inside ledger to the guard-rail of the lift below to allow access along a boarded lift.
When clear access is required on base lifts of tube and fitting scaffolds, the cross bracing may be omitted on the base lift provided the first lift does not exceed 2.7m, or the lift is knee braced. In either case, the loading capacity of the scaffold will be reduced.
Transoms or bearers, placed on top of ledgers and at right angles to them, run horizontally from back to front, defining the bay width. Main transoms provide support for standards by holding them in position as well as supporting boards or planks. Intermediate transoms are placed alongside main transoms to lend additional board support.
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In addition to standards, ledgers, and transoms, there are several other supportive elements that serve to reinforce the fundamental scaffolding. Braces include cross, or transverse, braces and façade, or longitudinal, braces. Cross braces run diagonally between ledgers and securely attach to standards to increase a structure’s overall rigidity. However, they can also be secured between ledgers, in which case they are simply called ledger braces. Façade braces help prevent a structure from swaying and are attached on the face of the scaffold, running diagonally along the length of the structure and securely attaching at every level. They are attached along the back of the scaffold as well.
Couplers help connect structural elements and come in several variants. To connect a ledger or transom to a standard, a right-angle coupler is used. If a transom supports a board and must be connected to a ledger, a putlog or single-coupler is used to connect the ledger to the transom. For any other angle of connection between scaffold piping, a swivel coupler is recommended.
Transoms are secured to ledgers with either right angle or putlog couplers unless braces are secured to them, in which case only right-angle couplers are acceptable. On boarded lifts, transoms will be spaced to ensure adequate supporting of the scaffold boards overlap 50mm over the transom. On non-boarded lifts and transoms should be secured at not more than 300mm from each standard or pair of standards.
Transom Beam: In scaffolding. A beam spanning a wider gap between standards than normal. Usually where wider access is required at ground level for vehicles and equipment. In modular systems they only have one attachment point each end to the standards.
Transom Truss :In scaffolding. A beam spanning a wider gap between standards than normal. Usually where wider access is required at ground level for vehicles and equipment. In modular systems they are deeper than transom beams and so have two attachment points at each end to the standards.
Above is a shot of a break in a scaffold to allow access to the inside of the building. It is spanned by two rather tired looking beams (at the bottom) and beefed up by two ladder beams (above) fixed to the standards with couplers.
No scaffold can remain stable or safe unless properly braced. Bracing should remain in position at all times to ensure this stability. There are two main types of bracing, as follows:
These are used to stop the framework from moving or swaying. They are attached to the front face of the structure and run along the length of the frame in a diagonal position and are fixed securely on every platform. This type of bracing should be installed every forth bay as well as the first and last bays, so the space between the braced bays is a maximum of three bays.
All bracing points should be 300mm off the connection node joint of the standards, transoms, and ledgers.
Fixed to the long face of the scaffold normally parallel to the face of the structure and is fitted to the outside row of standards. It can either run across the face of the scaffold to its full height at an angle of 45° or run in a zig-zag fashion to its full height.
Bracing should be provided at least every 3.0m along the scaffold. Bracing will be fixed to extended transoms with right angle couplers or to standards with swivel couplers. Where braces are fastened to transoms, the transoms should be fixed with right-angle couplers, (load-bearing) to the scaffold. Brace couplers may be used as an alternative.
This type of brace is mainly run diagonally in between the inside ledger and is fixed to the outside standards using a swivel coupler to boost the frameworks firmness. They can also be fixed ledger to ledger on the lifts above the base out. This brace should be added to every other bay or every other set of standards.
Fixed to join inner and outer alternate pairs of standards, fixing is by using right angle or brace couplers connected to the ledger or with swivel couplers to standards.
When a bay length is 1.5m or less, the bracing may be fixed to every third pair of standards. On boarded lifts, the brace would be fixed under the outside ledger to the inside ledger of the lift below to avoid the toe board. Bracing may be fixed from the inside ledger to the guardrail level of the below provided that every pair of standards are braced.
Ties connect the scaffold to the structure being built. Ties perform a dual function:
There are several different tie types. Those types of tie that are non-movable should be chosen,
where reasonably practicable, as they present fewer difficulties with maintenance or interference. Non-movable ties are assumed to be cast or drilled into the structure and will not need to be moved until final dismantling of the scaffold.
Ties should resist movement towards the building and away from the building. Where a tie cannot
resist movement towards the building, e.g. through ties, long bolts and wire ties, the tie should be supplemented by other measures, e.g. tubes butted against the building.
Ties should be securely coupled to both standards or to both ledgers, in accordance with the manufacturers recommendations, and be as near to a node point as possible. Where ties are attached to the ledgers, they should be attached not more than 300mm from a standard. Where this hinders access along a working platform, attachment to the inside ledger or standard only is permissible.
The vertical interval between ties should be determined in the scaffolding design and communicated to the scaffolding erector. In the case of system scaffolds, reference should be made to the manufacturer’s instructions.
Scaffolds of normal width of 1.25m should not be erected higher than the manufacturer’s instructions and to a maximum of 4m higher than the highest line of ties, unless to a specific design.
Working platforms should be wide enough and be sufficiently boarded out to allow safe passage of
persons along the platform. They should also be capable of resisting the loads imposed upon them,
including high wind loads that could dislodge the scaffold boards. The contractor in control of the
workplace must risk assess for potential adverse weather conditions.
Where a person could fall a distance liable to cause personal injury, the working platform should be
of the widths. A clear passageway, at least 450mm wide, should be maintained for persons to pass between stored materials and the side of the platform. They should be kept free from construction materials and waste to avoid causing an obstruction or a trip hazard.
A fall protection system (i.e. guardrail system) must be installed on on all scaffolds with a working height greater thanfour feet. The guardrail system shall be installed along all open sides and ends of the platform before being used as a work platform by employees. One exception is when the scaffold platform is within 14 inches of the face of the work.
Top rails (manufactured after 1/1/) must be 38 - 45 inches above the platform surface. (If manufactured before 1/1/, top rails must be between 36 - 45 inches above the platform surface.) Top rails must be capable of supporting at least 200 pounds applied in a downward or outward direction.
Mid rails must be installed at a height approximately midway between the top rail and the platform surface. Mid rails must be capable of supporting at least 150 pounds applied in a downward or outward direction.
Toe boards must be installed on work platforms where materials or tools will be in use. Toe boards must be installed not more than 1/4 inch above the platform and securely fastened. They may be made of solid material or mesh with openings no greater than 1 inch. Toe boards must be capable of withstanding at least 50 pounds applied in a downward or outward direction.
Additional protection from falling debris and other small objects must be provided in areas where personnel will be in the vicinity of scaffolds. Such protection may be in the form of:
Large or heavy materials stored on the scaffold platform must be located away from the edges of the work platform and secured, if necessary.
Scaffold access ladders should meet the following minimum standards:
Subject to provisions of this regulation no scaffold shall be used unless:
Every worker on a scaffold more than 10 feet above a lower level requires protection against falling. Though some regulations mandate the use of fall protection at six feet for the majority of building operations, the threshold for scaffolding operations is different. Because scaffolds are temporary structures built to assist workers who are building or dismantling other structures, and because scaffolds are less suitable for the use of fall protection at the time the first level is created, different thresholds are needed.
Depending on the kind of scaffold, several types of fall protection should be offered to the personnel:
Fall protection equipment is needed to prevent workers from falling when on a scaffold that is more than 10 feet above the ground. Depending on the kind of scaffolding, a different sort of fall protection will be used.
To keep you safe in the case of a fall, use a Personal Fall Arrest System (PFAS) made up of a harness, a connecting device, and an anchoring point. Any scaffolding, lift, or task higher than 6 feet in the air normally requires fall protection. Always be aware of the weight restrictions for your fall arrest equipment. If your weight exceeds the device’s maximum user weight rating, use a different device.
Devices for fall protection must be fastened to an authorized, stable anchor point. The body harness’ connection point needs to be close to shoulder level in the middle of the wearer’s back. Unless specifically designed for such use, personal fall arrest systems shouldn’t be fastened to guardrails, hoists, or any other object.
Before each use, a competent person must check your harness and lanyard for signs of wear, damage, and other deterioration. Anything that seems worn out or damaged should be taken out of service. Remove your harness and lanyard from service if it was involved in a fall until a competent can examine it. However, the best approach is to retire the harness from use following any falls.
All walkways inside a scaffolding system must have guardrails. Any guardrail system must have a top rail with a minimum weight capability of 200 pounds and be positioned within 9 ½ inches along, at least, one side of each walkway.
Both a personal fall arrest system and a guardrail system are required to safeguard workers on single-point or two-point adjustable suspension scaffolds, as well as those on self-contained adjustable scaffolds supported by ropes. The only thing you need is a guardrail system for self-contained adjustable scaffolds that are supported by a framework.
Workplaces that are more than 25 feet above the ground, water, or another surface where the use of ladders, scaffolds, catch platforms, temporary floors, safety lines, or safety belts is unfeasible must be equipped with safety nets. Safety nets should be installed as closely as possible to the working and walking surface.
Safety nets should have a mesh size no larger than 6 by 6 inches, a minimum impact resistance of 17,500 foot-pounds, and should reach 8 feet beyond the edge of the work area. Check the nets for wear or damage at least once every week.
Masonry scaffolds are composed of uprights, outriggers, cross braces, and base plates. These are frequently not even fitted or finished correctly, which renders them dangerous. The fact that scaffolding’s ends are not protected is one of the most common problems with railings. Companies often overlook enclosing the scaffold’s width from front to rear on each end.
The location of the cross-braces is another area that gets overlooked. People believe the guardrails are there to keep them safe. This is not entirely true. Depending on where the two braces cross, the laws specify that cross-bracing can only be a top rail or a mid-rail. Avoid both as it would be impossible for the two straight cross braces to cross in more than one location.
Scaffolding routinely appears on OSHA’s top ten most commonly reported infractions because of the complexity of the regulations. Only scaffolds that have been approved by the manufacturer may be utilized as anchor points in four-point suspended scaffolding. Having a competent person who is adequately trained and knowledgeable about the kinds of scaffolding you employ is crucial for this reason.
When using suspended scaffolding, you must always be tied off. You might be tethered to the hanging scaffold itself for a four-point suspension scaffold. Only scaffolds that have been approved by the manufacturer may be utilized as anchor points. This is significant since the forces of a fall might cause many scaffold systems to collapse.
As we said before, a personal fall arrest system (PFAS) prevents a person from striking a lower floor level or other objects in the event of a fall and is used when other types of fall protection are not practical or viable.
Every personal fall arrest system consists of an anchorage point, a connecting mechanism, and a complete body harness. Each of these three elements contributes significantly to preventing a hazardous fall. Knowing the three primary components of your PFAS and what each one does is crucial because they are all part of a fall protection program.
Any PFAS must only be used under the supervision of a competent person. A competent person must be able to recognize, assess, and deal with both current and foreseeable fall hazards.
A full body harness, also referred to as a safety harness, is the part of a personal fall arrest system that you wear. A worker is connected to the anchorage point by a full body harness, preventing them from falling and striking a lower level or item. A full body harness makes sure the worker is suspended upright after a fall and distributes the fall’s forces throughout the body.
A lanyard and a self-retracting lifeline are the two main categories of connection devices. The connection device, which is intended to attach to the full body harness and anchorage point, is what defines the duration and distance of a worker’s probable fall. Every connecting method has a particular situational application and must be worn, attached, and anchored by the person conducting the task.
A lanyard is an attachment point at each end of a short, flexible length of rope or webbing strap. At one end, lanyards are connected to a full body harness. On the other end, they are connected to a deceleration mechanism, a shock absorber, or an anchorage point. A lot of lanyards come with an internal or external shock absorber that is intended to lessen the force that a worker would experience in the event of a fall.
Like a lanyard, a self-retracting lifeline connects the worker’s safety harness to an anchorage point. However, there is one significant distinction. A self-retracting lifeline prevents the worker from hanging loosely and immediately retracts, limiting the worker’s free-fall distance to two feet or less.
An anchorage point is the third and last part of a personal fall arrest system. A person is supported before, during, and after a fall by an anchorage point. This is typically a component that is permanently fastened to the building being worked on. Steel is the most commonly used material for an anchor point. Any bolts and washers used as anchorage points should be examined to determine how well they can support the weight. It is important to clarify that it isn’t just the weight of the person, but they should be rated for a specific weight capacity.
One facet of fall protection safety is comprehending the function of a PFAS and its constituent parts. We suggest taking the Fall Protection & Personal Fall Arrest Systems course from Hard Hat Training if you want to learn more about fall protection systems.
Contact us to discuss your requirements of self climbing facade protection scaffold. Our experienced sales team can help you identify the options that best suit your needs.