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There are many different types of constructionÂ buildingsÂ such as residential, commercial or industrial.Â IndustrialÂ buildingsÂ are mainly used for manufacture & warehousing, offices, showrooms, sport, retailing, agricultural and horticulturalÂ buildings, recreation & leisure, swimming pool enclosures as well as many other aspects. If your business is in need of extra space; whether it is for storage or to conduct aspects of business, anÂ industrialÂ building, such as a warehouse may be the answer that your business is looking for.
IndustrialÂ buildings, such as the ones named above are available from many different building contractor teams and they are often available as both a permanent or temporary business solution. You may need the use of anÂ industrialÂ building as a way of housing certain equipment and supplies as well as providing you with a space that can be dedicated for you to undertake aspects of business. Depending on what you need theÂ industrialÂ building for depends on what type of building you have constructed. If you need the extra space as a place where people can do business then a more permanent structure may be in order. Also if you are planning on using yourÂ industrialÂ building as an added work space then it is important that you ensure the building is insulated and that your employees are protected.
Many of theÂ industrialÂ buildingsÂ that are open to you to use for your business provide you with a comfortable working environment and in many cases reduce energy through the quality and reliability which can be achieved with high performance insulation solutions. Also by choosing a reliable building contractor team to install yourÂ industrialÂ building you will be getting a workspace which creates a clean environment for all of your production, storage, material handling and infrastructure needs.
Many building contractor teams will design yourÂ industrialÂ buildingsÂ using cladding and lining and will incorporate windows and doors that in some cases are double glazed as well as being tough when it comes to security. You will be able to decide what features are and aren't included on yourÂ industrialÂ building, meaning from the start you will know exactly what you are buying.
When you are deciding on including anÂ industrialÂ building into your workplace you need to ensure that the execution of the project is successful. One way of making sure that this happens is by conducting effective planning as this is essential to ensure that you get what you want from yourÂ industrialÂ building. During your planning for yourÂ industrialÂ building you should consider aspects such as the environmental impact of the job, the success of the scheduling, budgeting and site safety as well as the availability of materials, logistics and the inconvenience to the public caused by construction delays, preparing tender documents, etc.
If you are hoping to gain the extra help from the use of anÂ industrialÂ building then it is highly important that you gain the help of a professional building contractor team to construct your industrialÂ building.
Identify the Differences of the Prefabricated and Pre Engineered Buildings.
Prefabricated building is a type of building that consists that of several factory built components or units that are assembled on site to complete the unit. Its Prefabricated / Pre-engineered components away from the site and bringing them to site and assembling. These methods reduce construction time at the site, facilitate better quality control and reduce labour component which involves in the site.
The term 'prefabricated' may refer to buildings built in components (e.g. panels), modules (modular homes) or transportable sections (manufactured homes), and may also be used to refer to mobile homes, i.e. houses on wheels. Although similar in nature, the methods and design of the three can vary wildly. There are two-level home plans, as well as custom home plans. There are also large differences in the construction types. Mobile and manufactured houses are constructed in accordance with the HUD building codes in the U.S. while modular houses are constructed in accordance with the IBC (International Building Code).
Modular homes are homes that are created in sections, and then transported to the home site for construction and installation. These are typically installed and treated like a regular house, for financing, appraisal and construction purposes, and are usually the most expensive of the three. Although the sections of the house are prefabricated, the sections, or modules, are put together at the construction much like a typical home. Manufactured and mobile houses are rated as personal property and depreciate over time.
Manufactured homes refer to homes that are built onto steel beams, and are transported in complete sections to the home site, where they are assembled.
Mobile homes are homes built on wheels, which are able to be moved from place to place.
Mobile homes and manufactured homes can be placed in mobile home parks, and manufactured homes can also be placed on private land, providing the land is appropriately zoned for manufactured homes.
As far as getting set up, prefabricated buildings can be erected rather quickly - some in as little as 45 days. Companies can start concentrating on making money rather than concerning themselves with when their building will be finished.
Prefabricated buildings can be constructed at almost half the cost of a traditional building. For a basic structure such as a portable office or classroom, expect to pay about $35 per square foot. More complex prefabricated buildings - medical clinics and retail facilities - will cost you close to $200 per square foot. While not exactly a drop in the bucket, it's still more affordable than traditional construction, particularly if the prefabricated buildings are only going to be used for a fixed period of time.
For those companies who look beyond price and convenience, prefabricated buildings do have a few downsides. The most obvious is the look and feel. At their most basic, prefabricated buildings are meant to be quick, affordable solutions - so they aren't the prettiest structures in the world. Elevated entrances and shorter ceilings don't really add to the décor, but if you are willing to spend a bit more, you can upgrade your prefabricated buildings to have more stylish designs.
The types of materials used for prefabricated buildings are usually aluminum,Â wood, steel, fiberglass, and concrete. The steel used in these structures is specially treated to resist corrosion, rust, and fire. The use of plastics and other composite materials offer a less expensive option for surface materials without sacrificing durability or quality. The construction of the components of the prefabricated building is accomplished inside the factory where the plumbing and electrical systems are tested before they are exported to their destinations. The wall finishes andÂ countertopsÂ are also installed inside the factory. Although customization is available, prefabrication businesses are able to buy much of their material in bulk and thus are able to pass on the savings to their buyers.Â
InÂ structural engineering, aÂ pre-engineered buildingÂ (PEB) is designed by a manufacturer to be fabricated using a pre-determined inventory of raw materials and manufacturing methods that can efficiently satisfy a wide range of structural and aesthetic design requirements. Within some geographic industry sectors these buildings are also called Pre-Engineered Metal Buildings (PEMB) or, as is becoming increasingly common due to the reduced amount of pre-engineering involved in custom computer aided designs, simply, Engineered Metal Buildings (EMB).
Historically, the primary framing structure of a pre-engineered building is an assembly of "I" shaped members, often referred asÂ "I" beams. In pre-engineered buildings, the "I" beams used are usually formed by welding together steel plates to form the "I" section. The "I" beams are then field-assembled (e.g. bolted connections) to form the entire frame of the pre-engineered building. Some manufacturers taper the framing members (varying in web depth) according to the local loading effects. Larger plate dimensions are used in areas of higher load effects.
Other forms of primary framing can include trusses, mill sections rather than 3-plate welded, castellated beams, etc. The choice of economic form can vary depending on factors such as local capabilities (e.g. manufacturing, transportation, construction) and variations in material vs. labour costs.
Typically, primary frames are 2D type frames (i.e. may be analyzed using 2-Dimensional techniques). Advances in computer aided design technology, materials and manufacturing capabilities have assisted a growth in alternate forms of Pre-engineered building such as the Tension fabric buildingÂ and more sophisticated analysis (e.g. 3-Dimensional) as is required by some building codes.
Cold formed Z and C-shaped members may be used as secondary structural elements to fasten and support the external cladding.
Roll-formed profiled steel sheet, wood, tensioned fabric, precast concrete, masonry block, glass curtain wall or other materials may be used for the external cladding of the building.
In order to accurately design a pre-engineered building, engineers consider the clear span between bearing points, bay spacing, roof slope, live loads, dead loads, collateral loads, wind uplift, deflection criteria, internal crane system and maximum practical size and weight of fabricated members. Historically, pre-engineered building manufacturers have developed pre-calculated tables for different structural elements in order to allow designers to select the most efficient I beams size for their projects. However, the table selection procedures are becoming rare with the evolution in computer aided custom designs.
While pre-engineered buildings can be adapted to suit a wide variety of structural applications, the greatest economy will be realized when utilizing standard details. An efficiently designed pre-engineered building can be lighter than the conventional steel buildings by up to 30%. Lighter weight equates to less steel and a potential price savings in structural framework.
Applications of Pre Engineered Buildings (PEB)
Vehicle parking sheds
Indoor stadium roofs
Outdoor stadium canopies
Railway platform shelters
Advantages of Pre Engineered Buildings
Reduced construction time:
Buildings are typically delivered in just a few weeks after approval of drawings. Foundation and anchor bolts are cast parallel with finished, ready for the site bolting. Our study shows that in India the use of PEB will reduce total construction time of the project by at least 50%. This also allows faster occupancy and earlier realization of revenue.
Due to the systems approach, there is a significant saving in design, manufacturing and on site erection cost. The secondary members and cladding nest together reducing transportation cost.
Flexibility of expansion:
Buildings can be easily expanded in length by adding additional bays. Also expansion in width and height is possible by pre designing for future expansion.
Large clear spans:
Buildings can be supplied to around 80M clear spans.
As buildings are manufactured completely in the factory under controlled conditions the quality is assured.
Buildings are supplied with high quality paint systems for cladding and steel to suit ambient conditions at the site, which results in long durability and low maintenance coats.
Energy efficient roofing and wall systems:Â
Buildings can be supplied with polyurethane insulated panels or fiberglass blankets insulation to achieve required "U" values.
Building can be supplied with various types of fascias, canopies, and curved eaves and are designed to receive pre cast concrete wall panels, curtain walls, block walls and other wall systems.
Single source responsibility:
As the complete building package is supplied by a single vendor, compatibility of all the building components and accessories is assured. This is one of the major benefits of the pre engineered building systems.
Investigate various types of materials, which can be used for the factory and residential Buildings in this project.
Materials used for pre-fabricated buildings
Prefabricated building materials are used for buildings that are manufactured off site and shipped later to assemble at the final location. Some of the commonly used prefabricated building materials are aluminum, steel, wood, fiberglass and concrete.
Prefabricated metal buildings use galvanized steel and galvalume as the chief materials for building. Galvalume is a form of steel coated with aluminum-zinc. This is to protect the building against corrosion, rust and fire. It also provides a sturdy and protective covering to the prefabricated building. Almost all the components of a metal building such as beams, frames, columns, walls and roofs, are made of steel. Most prefabricated military buildings use steel or aluminum frames. Synthetic materials are used for the walls and roofs. To provide enhanced security, a combination of both metal and cloth materials are used. Plastic flooring materials can be quickly assembled and are very durable.
Prefabricated building materials used for small prefabricated buildings are steel, wood, fiberglass, plastic or aluminum materials. These materials are cheaper than regular brick and concrete buildings. Materials like steel, fiberglass, wood and aluminum are used as prefabricated building materials for sports buildings. These materials provide flexibility and are preferred for making structures and accessories like stands and seats for stadium and gyms.
For making low cost houses, prefabricated materials like straw bale, Ferro cement, Calcium silicate products, composites and other cheap wood based materials are currently being used. Calcium silicate bricks are strong and durable. Ferro cement consists of a cement matrix reinforced with a mesh of closely-spaced iron rods or wires. In this type of construction, the techniques used are simple and quick.
Using prefabricated materials one can make durable, water and fire resistant and cheap prefabricated buildings. Most of the prefabricated building materials are eco-friendly and affordable.
Materials used for pre-engineered buildings
Steel / Stainless steel
Galvalume roof sheeting
Stainless steel capped fasteners
Silicon zed polyester baked-on enamel paint
Various types of materials
For prefabricated buildings, steel and galvalume materials are used. Galvalume is a form of steel coated with aluminum-zinc. This is to protect the building against corrosion, rust and fire. It also provides a sturdy and protective covering to the prefabricated building. Most of components are built in steel in prefabrication buildings such as beams, frames, columns, walls and roofs, are made of steel.
Most prefabricated buildings use aluminum as a material for frames. It can be widow frames or door frames. Because of its light weight it is very useful for prefabrication building production.
These materials provide flexibility and are preferred for making structures and accessories like stands and seats for stadium and gyms. And wood use for prefabricated buildings for some of the components. It is not a most probably used material. This material is used for making of law cost prefabricated homes.
The fiberglass material is used for the partition walls in the buildings. And its light weight is useful for constructing prefabricated buildings. And for doors and window frames, doors fiberglass is used.
Advantages of Per Fabricated Buildings
Prefabricated homes can be ordered and transported straight to your block.Â You can organize the stumping and plumbing and electrical connections or have it pre ordered into the overall package.
Prefabricated homes cause less damage to the environment than conventional brick homes.Â They can be mass produced or fabricated to your design and are quick to build so it will save you rent as brick homes tend to be dragged out with different contractors' being involved.
They will cost a lot less, than a double brick home by far.Â They can be insulated to reduce the cost of heating and cooling. Not only that they are environmentally friendly.
The realÂ beautyÂ of one of these is if you have a real bad neighbor you can up and take your home and chattels to another town without any problems.
As it saves time
It saves money and labour
Enables money and standardization.
Enhances aesthetic appeal.
It is lightweight and easy to transport.
Easy to installing and maintaining: i.e. rust, fire, and pest retardant and insulated.
It is re-locatable and eco-friendly.
The disadvantages of prefabricated homes
The cost of your prefabricated home will depend on the site your home will be put on.Â Site costs will vary from block to block. If you are doing the stumping etc yourself then that is not a problem.Â If they need to factor that into the price they will need to make varying changes to prices due to level and position of the block where the prefabricated home will be built.
Your choice of prefabricated home will be affected by your particular budget.Â Low cost designs may suit those on a tight budget.Â Then if you can afford the better styles, then price may not affect your decision.
The better high quality designs are made for the higher income families and could be out of your price range.
Prefabricated homes are improving like other forms of buildings and the main advantage of a prefabricated home is the potential to reduce the harmful impact on our environment.Â This is one of the world's biggest concerns these days.
Materials used for pre-engineered buildings
Steel / Stainless steel
Galvalume roof sheeting
Stainless steel capped fasteners
Silicon zed polyester baked-on enamel paint
The Advantages of pre-engineered buildings
Low cost if choosing manufacturer's standard package/inventory and no add on
Open clear span
Can be easily expanded to grow with needs
The disadvantages of pre-engineered buildings
Marginal design, material and construction
Not energy efficient
Higher lifetime maintenance
Not durable for long term use, generally last 10 to 15 years
May not include all construction/fit-up needed for the building to serve the intended purpose.
No secondary roof membrane
Usually no internal finished walls
Pre-engineered steel fabric buildings vs. Conventional steel buildings
Steel Fabric Structures
Conventional Steel Buildings
Price per square foot is about 30% lower than conventional steel
More expensive than a pre-engineered steel fabric building
The building and fabric cover is virtually maintenance free. The fabric will not attract or hold dirt contaminants and proves to be self-cleaning
Shingling or painting may be
necessary to maintain the outside of the building
Clear span throughout building does not interfere with any operations
Columns or posts may need to be in place to maintain structural
integrity of the building
Our buildings are made with hot
dipped galvanized steel and are corrosion resistant
Due to the exterior of the building being exposed in all weather conditions, corrosion may become an issue
Our membrane fabric cover had
non-conductive qualities keeping
buildings cooler in the summer
and warmer in the winter
Steel buildings are conductive of
heat, creating a virtual oven in
hot weather conditions
Lower costs for lighting, heat,
and A/C due to non-conductive
Operational costs are higher for
lighting, heat, and A/C
Our buildings are easily expandable and reloadable. Can be used as a temporary and permanent structure.
Steel buildings are permanent and cannot be relocated. Expansion will be timely and costly, if possible.
Foundation can be as little as
Footings at truss and end column base plate locations. Foundation requirements are typically a fraction of that of similar conventional buildings.
Extensive, heavy foundation
Installation and delivery
Depending on the size of the
Structure installation takes an average of 7-10 days. Delivery after order takes about 6-12 weeks.
Delivery of material averages
From 20 to 26 weeks. Installation Time is more than double that of a steel fabric structure.
Sound absorbing covers keep
building quiet even during adverse weather conditions
Buildings are loud during rain and hail storms creating unpleasant working conditions
Our membrane fabric design
allows natural light to filter through the building while keeping out moisture and condensation
Condensation is a known problem in steel buildings and can damage the building and its contents
Pre engineered buildings are on the average 30% lighter because of the efficient use of steel. Primary framing members are tapered built up section. With the large depths in areas of higher stress.
Secondary members are light weight roll formed "Z" or "C" shaped members.
Primary steel members are selected hot rolled "T" sections. Which are, in many segments of the members heavier than what is actually required by design? Members have constant cross section regardless of the varying magnitude of the local stresses
along the member length
Secondary members are selected from standard hot rolled sections which are much heavier.
Quick and efficient: since PEB's are mainly formed by standard sections and connections design, time is significantly reduced. Basic design based on international design codes are used over and over.
Specialized computer analysis design programs optimize material required. Drafting is also computerized using standard detail that minimizes the use of project custom details.
Design shop detail sketches and erection drawings are supplied free of cost by the manufacturer. Approval drawing is usually prepared within in 2 weeks.
PEB designers design and detail PEB buildings almost every day of the year resulting in improving the quality of designs every time they work
Each conventional steel structure is designed from scratch with fewer design aids available to the engineer.
Substantial engineering and detailing work is required from the very basic is required by the consultant with fewer design aids.
Extensive amount of consultant time is devoted to the alterations that have to be done.
As each project is a new project engineers need more time to develop the designs and details of the unique structure.
Since the connection of compounds is standard the learning curve of erection for each subsequent project is faster.
Periodic free of charge erection is provided at the site by the manufacturer.
The connections are normally complicated and differ from project to project resulting tin increasing the time for erection of the buildings.
There has to be separate allocation of labour for the purpose of erection.
Erection cost and time
Both costs and time of erection are accurately known based upon extensive experience with similar buildings.
The erection process is faster and much easier with very less requirement for equipment.
Typically, conventional steel buildings are 20% more expensive than PEB in most of the cases, the erection costs and time are not estimated accurately.
Erection process is slow and extensive field labors required. Heavy equipment is also needed.
Outstanding architectural design can be achieved at low cost using standard architectural details and interfaces.
Special architectural design and features must be developed for each project which often requires research and thus resulting in higher cost.
Sourcing and coordination
Building is supplied complete with all accessories including erection for a single "ONE STOP SOURCE".
Many sources of supply are there so it becomes difficult to co ordinate and handle the things.
Designed to fit the system with standardized and inter changeable parts. Including pre designed flashing and trims. Building accessories are mass produced for economy and are available with the building.
Every project requires different and special design for accessories and special sourcing for each item. Flashing and trims must be uniquely designed and fabricated.
All project records are safely and orderly kept in electronic format which makes it easy for the owner to obtain a copy of his building record at any time.
Future expansion is very easy and simple.
It would be difficult to obtain project records after a long period of time. It is required to contact more than one number of parties.
Future expansion is most tedious and more costly.
Safety and responsibility
Single source of responsibility is there because the entire job is being done by one supplier.
Multiple responsibilities can result in question of who is responsible when the components do not fit in properly, insufficient material is supplied or parts fail to perform particularly at the supplier/contractor interface.
All components have been specified and designed specially to act together as a system for maximum efficiency, precise fir and peak performance in the field.
Experience with similar buildings, in actual field conditions worldwide, has resulted in design improvements over time, which allows dependable prediction of performance.
Components are custom designed for a specific application on a specific job. Design and detailing errors are possible when assembling the diverse components into unique buildings.
Each building design is unique, so predication, of how components will perform together is uncertain. Materials which have performed well in some climates may not do well in other conditions.
Explain the appropriateness, advantages and disadvantages of using prefabricated buildings in the project
The advantages of having prefabricated buildings in this project
Prefabricated buildings can be ordered and transported straight to your block.Â Client can organize the stumping and plumbing and electrical connections or have it pre ordered into the overall package. Prefabricated buildings cause less damage to the environment than conventional brick buildings.Â They can be mass produced or fabricated to the design and are quick to build so it will save you rent as brick buildings tend to be dragged out with different contractors' being involved. They will cost a lot less, than a double brick building by far.Â They can be insulated to reduce the cost of heating and cooling. Not only that they are environmentally friendly.
The disadvantages of having prefabricated buildings in this project
The cost of your prefabricated building will depend on the site your home will be put on.Â Site costs will vary from block to block. If you are doing the stumping etc yourself then that is not a problem.Â If they need to factor that into the price they will need to make varying changes to prices due to level and position of the block where the prefabricated home will be built.
The choice of prefabricated building will be affected by your particular budget.Â Low cost designs may suit those on a tight budget.Â Then if you can afford the better styles, then price may not affect your decision. Prefabricated homes are improving like other forms of buildings and the main advantage of a prefabricated home is the potential to reduce the harmful impact on our environment.Â This is one of the world's biggest concerns these days.
The advantage of having a prefabricated steel building
Steel is a remarkable material that has been steadily increasing in popularity for construction. It is 66% recyclable, which offers both environmental and financial benefits, and is especially strong and durable. There are a number of options available for building with steel, and one of the most innovative of those options are pre-engineered steel buildings. They are planned, designed and almost pre-built at the factory itself. They just have to be assembled after they reach the building site. They are pre-drilled, pre-cut and pre-welded and just need to be bolted together. This can often be done quickly and with a minimum of professional assistance, and sometimes with none at all.
They are quicker, easier and almost 50% less expensive than conventional buildings. Besides, they can be designed as per exact specifications. Elements of the site, other buildings in the area, proposed purpose, and other elements can be taken into consideration.
This is the reason for the increasing use of pre-engineered steel buildings for schools, offices, houses, stores, churches and recreational places.
Pre-engineered steel buildings, which have no support columns, are known as clear-span buildings. Though they maximize floor space, they cannot be expanded in width. On the other hand, multi-span buildings have unlimited scope for expansion and are thus are often a popular choice for offices and residential buildings.
Pre-engineered steel homes have also become very popular in recent years. They offer affordability and flexibility, among many other benefits. There are two kinds of pre-engineered steel buildings: modular and manufactured homes. The only difference is that manufactured homes need not be built as per the building codes, unlike modular homes. For this reason, modular homes are often considered to be more sturdy and reliable.
Whether you're creating a manufactured home, modular home, or even a new office, pre-engineered steel buildings offer a vast array of affordable and durable options.
Specification for a Pre-fabricated building
Panels for a Pre-fabricated building
The prefabricated building wall and ceiling panels are nominal 3-inch thick with standard sizes from four feet wide by eight feet tall to four feet wide by ten feet tall. Custom heights over ten feet are also available. Panel building construction varies over a wide range. Standard Metal wall panels will have either Embossed 24 ga. Pre-painted steel or .019 pre-painted aluminum skins laminated to 1/8" tempered hardboard both sides of honeycomb or expanded polystyrene foam core. Many more custom panel configurations are available.
Posts for a Pre-fabricated building
Posts are to be of four-piece design to form a non-progressive wall system. Cavity of posts will allow use of approved steel electrical boxes that are now required by building codes .Prefabricated building posts shall also act as raceways for phone lines, data lines, and other electrical lines. The structural elements of the posts shall be connected by machine bolts and nuts no more than 18" center line. All extrusions shall be 6063-T5 aluminum, minimum .062 thicknesses, with a clear anodized finish.
Corner posts will be 3" x 3" Steel Tube welded to Structural Steel Channel base frame.
Base channel provides support for wall panels and posts while allowing space for anchors or post uplift connectors. Its low profile design is aesthetically pleasing and eliminates the need for additional base molding. Materials for prefabricated building shall be 6063-T5 aluminum, minimum .062 thick, and clear anodized finish.
Capping channel acts as a support for vertical deck loads in addition to serving as a continuous diaphragm member. Material is 6063-T5 aluminum, minimum .062 thicknesses, and clear anodized finish.
Doors will be 1 3/4" thick and standard 42" wide by 80" tall to accommodate equipment or furniture. Door material will match wall panels and be framed in an aluminum channel for heavy traffic areas. Door jamb is a heavy duty extrusion. All doors are factory pre-hung with hinges and door lockset. Windows are 2 'x 2' with 1/4" tempered safety glass. Extrusions are 6063-T5 aluminum, minimum .062 thicknesses, with clear anodized finish.
Standard fixed windows are 44" wide by 40" tall with 3/16" tempered safety glass installed in aluminum frame. Window units are completely modular. Horizontal sliding and pass thru windows can also be provided. Frames are 6063-T5 aluminum, .062 minimum thicknesses, with clear anodized finish.
Standard Steel faced, foam core, flat metal panels.
Optional Gable Roof Panels with 3 in 12 pitch; panels are Steel faced with foam core.
Optional heavy duty white enameled steel T-BAR hung from roof by 12 ga. galvanized ceiling wire and self tapping sheet metal screws. Ceiling tiles are 2' x 4', 5/8" thick, Mineral board. Additional R-19 insulation is optional.
Surface Mount Fluorescent light fixtures are 2' X 4', 4-TUBE, 120v, less tubes. Duplex outlets and light switches, 120v, with approved electrical box and post prep. Sub panel and breakers.
Standard 1 1/8" thick Plywood with 12" x 12" x 1/8" vinyl floor tile. Optional Steel or Aluminum Diamond Plate.
Thru wall systems or central air systems are available. Consult factory for design assistance. Specifications are subject to change without notice.
Some Design views for the Pre Fabricated Buildings and Houses