In Civil engineering, a pre-engineered building (PEB) is designed by a PEB supplier or PEB manufacturer, to be fabricated using best-suited inventory of raw materials available from all sources and manufacturing methods that can efficiently satisfy a wide range of structural and aesthetic design requirements. This system is, without doubt, one of the fastest growing building systems in the world. The advantages that it offers appeal to all parties involved in the project.
After all, who can resist a building system that offers speed, quality, and value?
⧪ PRE ENGINEERED BUILDINGS
Pre-engineered buildings are factory-built buildings of steel that are shipped to the site and bolted together. What distinguishes them from other buildings is that the contractor also designs the building - a practice called design & build. This style of construction is ideally suited to industrial buildings and warehouses; it is cheap, very fast to erect, and can also be dismantled and moved to another site - more on that later. These structures are sometimes called 'metal boxes' or 'tin sheds' by laymen - they are essentially rectangular boxes enclosed in a skin of corrugated metal sheeting.
Great speed is achieved because while the foundations and floor slab are being constructed, the beams and columns - the structural system - are being fabricated in the factory. Once the foundations and floor are done, the columns are shipped to the site, lifted into place by cranes, and bolted together. the pre-engineered building has polycarbonate strips in the roof to allow for uniform natural lighting. Ten foot (3m) high concrete block walls on the periphery contain windows and provide security; above that, the only walling material is a thin corrugated metal sheet.
⧪ STRUCTURAL SYSTEMS
The structural system of pre-engineered steel buildings gives it its speed and flexibility. This system consists of the factory-fabricated and factory-painted steel column and beam segments that are simply bolted together at the site. The columns and beams are custom-fabricated I-section members that have an end plate with holes for bolting at both ends. These are made by cutting steel plates of the desired thickness and welding them together to make I sections.
The cutting and welding are done by industrial robots for speed and accuracy; operators will simply feed a CAD drawing of the beams into the machines, and they do the rest. This production line style of work makes for great speed and consistency in fabrication. The shape of the beams can be tailored to optimum structural efficiency: they are deeper where the forces are greater, and shallow where they are not. This is one form of construction in which the structures are designed to carry exactly the loads envisioned and no more.
Pre-engineered building before the roof skin has been installed. Note that the shape of the beams follows the forces in them; the beams are deeper where the forces are greater.
⧪ ERECTION
Each piece of the system is very much like - an I section with end plates for bolting. The painted steel sections are lifted into place by crane, and then bolted together by construction workers who have climbed to the appropriate position. In large buildings, construction can start with two cranes working inwards from both ends; as they come together, one crane is removed and the other finishes the job. Usually, each connection calls for six to twenty bolts to be installed. Bolts are to be tightened to exactly the right amount of torque using a torque wrench.
⧪ FOUNDATIONS AND FLOOR SLAB
The foundations for pre-engineered metal buildings are made with conventional concrete systems, usually open foundations. Since these structures are usually quite large, they attract a fair amount of wind forces. Wind can cause a net upwards force on a building, called uplift. Since these structures are very light (they can weigh as little as 50 kg per square meter, excluding the foundations and floor slab), the foundations are designed to firmly anchor the structures to the ground, preventing them from being blown away by the wind. The floor system for industrial and storage buildings is usually a thick (about 8" to 12" / 200 to 300mm) concrete grade slab that rests directly on the prepared earth beneath it. The concrete can be topped with a thin, abrasion-resistant smooth coating called an epoxy floor or polyurethane floor if desired.
⧪ CLADDING AND ROOFING - THE BUILDING ENVELOPE
The most economical cladding for these structures is light corrugated metal sheeting, on both the roof and the external walls. These steel sheets, barely 0.5mm thick, are coated with an aluminum-zinc alloy for corrosion protection on both sides, and come with an attractive, durable paint finish on the outside. These sheets are installed over a grid of purlins, a steel member that rests on the main structural frame and supports the roofing material. In pre-engineered buildings, cold formed Z sections are the member of choice for purlins.
Before installing the sheets, contractors will install layers of insulation and vapor barriers. Rolls of glass wool or mineral wool are the most common type of insulation for such buildings. Since there is no inner wall over which to fix these layers, a layer of galvanized chicken wire mesh is first laid over the purlins. Over this, the insulation and vapor barriers are laid, and then the corrugated sheets are laid. The sheets are fixed with self-tapping screws that run through the sheets and layers of insulation directly into the purlins. The purlins, chicken mesh, and insulation are thus visible from below and can be left as such or covered with a false ceiling. Polycarbonate skylights can be installed in the roof sheeting to create natural lighting.
It is common for industrial buildings to have a masonry wall up to a height of 10 or 15 feet (3 to 5m). This allows doors and windows to be easily fitted and provides security. This wall can be built behind the metal sheeting, making it invisible from the outside.
After all, who can resist a building system that offers speed, quality, and value?
⧪ PRE ENGINEERED BUILDINGS
Pre-engineered buildings are factory-built buildings of steel that are shipped to the site and bolted together. What distinguishes them from other buildings is that the contractor also designs the building - a practice called design & build. This style of construction is ideally suited to industrial buildings and warehouses; it is cheap, very fast to erect, and can also be dismantled and moved to another site - more on that later. These structures are sometimes called 'metal boxes' or 'tin sheds' by laymen - they are essentially rectangular boxes enclosed in a skin of corrugated metal sheeting.
Great speed is achieved because while the foundations and floor slab are being constructed, the beams and columns - the structural system - are being fabricated in the factory. Once the foundations and floor are done, the columns are shipped to the site, lifted into place by cranes, and bolted together. the pre-engineered building has polycarbonate strips in the roof to allow for uniform natural lighting. Ten foot (3m) high concrete block walls on the periphery contain windows and provide security; above that, the only walling material is a thin corrugated metal sheet.
⧪ STRUCTURAL SYSTEMS
The structural system of pre-engineered steel buildings gives it its speed and flexibility. This system consists of the factory-fabricated and factory-painted steel column and beam segments that are simply bolted together at the site. The columns and beams are custom-fabricated I-section members that have an end plate with holes for bolting at both ends. These are made by cutting steel plates of the desired thickness and welding them together to make I sections.
The cutting and welding are done by industrial robots for speed and accuracy; operators will simply feed a CAD drawing of the beams into the machines, and they do the rest. This production line style of work makes for great speed and consistency in fabrication. The shape of the beams can be tailored to optimum structural efficiency: they are deeper where the forces are greater, and shallow where they are not. This is one form of construction in which the structures are designed to carry exactly the loads envisioned and no more.
Pre-engineered building before the roof skin has been installed. Note that the shape of the beams follows the forces in them; the beams are deeper where the forces are greater.
⧪ ERECTION
Each piece of the system is very much like - an I section with end plates for bolting. The painted steel sections are lifted into place by crane, and then bolted together by construction workers who have climbed to the appropriate position. In large buildings, construction can start with two cranes working inwards from both ends; as they come together, one crane is removed and the other finishes the job. Usually, each connection calls for six to twenty bolts to be installed. Bolts are to be tightened to exactly the right amount of torque using a torque wrench.
⧪ FOUNDATIONS AND FLOOR SLAB
The foundations for pre-engineered metal buildings are made with conventional concrete systems, usually open foundations. Since these structures are usually quite large, they attract a fair amount of wind forces. Wind can cause a net upwards force on a building, called uplift. Since these structures are very light (they can weigh as little as 50 kg per square meter, excluding the foundations and floor slab), the foundations are designed to firmly anchor the structures to the ground, preventing them from being blown away by the wind. The floor system for industrial and storage buildings is usually a thick (about 8" to 12" / 200 to 300mm) concrete grade slab that rests directly on the prepared earth beneath it. The concrete can be topped with a thin, abrasion-resistant smooth coating called an epoxy floor or polyurethane floor if desired.
⧪ CLADDING AND ROOFING - THE BUILDING ENVELOPE
The most economical cladding for these structures is light corrugated metal sheeting, on both the roof and the external walls. These steel sheets, barely 0.5mm thick, are coated with an aluminum-zinc alloy for corrosion protection on both sides, and come with an attractive, durable paint finish on the outside. These sheets are installed over a grid of purlins, a steel member that rests on the main structural frame and supports the roofing material. In pre-engineered buildings, cold formed Z sections are the member of choice for purlins.
Before installing the sheets, contractors will install layers of insulation and vapor barriers. Rolls of glass wool or mineral wool are the most common type of insulation for such buildings. Since there is no inner wall over which to fix these layers, a layer of galvanized chicken wire mesh is first laid over the purlins. Over this, the insulation and vapor barriers are laid, and then the corrugated sheets are laid. The sheets are fixed with self-tapping screws that run through the sheets and layers of insulation directly into the purlins. The purlins, chicken mesh, and insulation are thus visible from below and can be left as such or covered with a false ceiling. Polycarbonate skylights can be installed in the roof sheeting to create natural lighting.
It is common for industrial buildings to have a masonry wall up to a height of 10 or 15 feet (3 to 5m). This allows doors and windows to be easily fitted and provides security. This wall can be built behind the metal sheeting, making it invisible from the outside.
No comments:
Post a Comment