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Prefabricated Construction Method

Prefabricated Construction Method

Prefabricated Construction Method
Prefabricated construction is a building process in which elements or modules of the structure are prefabricated at plants, then transported to the construction site for installation. Using this method can reduce  the time of building, also saving construction cost. Prefabricated construction is now widely applied for new houses or other building structures like bridge, tunnels,  culverts, water supply system…
The benefits of prefabricated construction method is from the  fabrication of standard components on factory floor. This  production is less time consumption compared to actual condition of construction process. The prefabricated elements are transported to the site for installing process. At the site, the modules are unloaded, moved into position with the support of heavy cranes, and assembled to form a designed building.
Together with the fast assembly, prefabricated construction also saves a lot of money on the construction project. By using standard patterns, the building materials are saved at the manufacturing factories. This help to reduce the waste in formwork and other materials that can occur during traditional building procedures.
Another considerable  profit using prefabricated construction method is the energy efficiency. Because the prefab elements of a panelized home are precut, they fit snugly together, making for a tighter edifice. This means less effort for heating and cooling, resulted  in lower energy bills.
The rapid development of prefabricated houses has led to the increasing of construction templates that homeowners have more choice for designs of their houses. By combining these templates, it is possible to design the layout of the house, specify the dimensions of each room, and build a home that is exactly to the specification of the owners. There are also complex building plans for prefabricated construction that can be adjusted slightly and still have the benefit of using materials of standard lengths, widths, and textures.
Prefabricated houses are not the only type of construction structures that can be produced using prefabrication construction method. As mentioned above, this method is widely used in many types of constructions like bridges, culverts or even swimming pools.

Strong, elastic 'smart materials' aid design of earthquake-resistant bridges

Strong, elastic 'smart materials' aid design of earthquake-resistant bridges

Strong, elastic 'smart materials' aid design of earthquake-resistant bridges
Traditional bridge columns are constructed from concrete and reinforced steel, which are seldom effective against earthquakes. But new research suggests that replacing concrete and steel with smart materials is a good alternative. From left: cement-polyvinyl fiber mixture; fiberglass column; carbon fiber column; nickel titanium shape memory alloy, or nitinol.
Bridges are a main component of the transportation infrastructure as we know it today. There are no less than 575,000 highway bridges nationwide, and more than $5 billion are allocated yearly from the federal budget for bridge repairs.
Over the past couple of decades, increasing seismic activity around the world has been identified as an impending threat to the strength and well-being of our bridges. Earthquakes have caused bridge collapses in the U.S., Japan, Taiwan, China, Chile, Turkey, and elsewhere. Therefore, we need to find ways to minimize seismic effects on bridges, both by improving existing bridges and refining specifications and construction materials for future bridges.
A large majority of bridges are made of steel and concrete. While this combination is convenient and economical, steel-concrete bridges don't hold up as well in strong earthquakes (7.0 magnitude or higher). Conventional reinforced columns rely on the steel and concrete to dissipate energy during strong earthquakes, potentially creating permanent deformation and damage in the column and making the column unusable.
Under earthquake loading, engineers allow for damage in column hinges to dissipate energy and prevent total bridge collapse. While that practice is widely accepted, the effects of hinge damage can interfere with disaster recovery operations and have a major economic impact on the community.
With funding from the National Science Foundation (NSF) and using NSF's George E. Brown, Jr. Network for Earthquake Engineering Simulation (NEES), civil engineer M. Saiid Saiidi of the University of Nevada, Reno (UNR), and his colleagues have discovered a solution. They've identified several smart materials as alternatives to steel and concrete in bridges.
Shape memory alloys (SMAs) are unique in their ability to endure heavy strain and still return to their original state, either through heating or superelasticity. SMAs demonstrate an ability to re-center bridge columns, which minimizes the permanent tilt columns can experience after an earthquake.
Nickel titanium, or nitinol, the shape memory alloy tested in the UNR project, has a unique ability even amongst SMAs. While the majority of SMAs are only temperature-sensitive, meaning that they require a heat source to return to their original shape, Nitinol is also superelastic. This means that it can absorb the stress imposed by an earthquake and return to its original shape, which makes nitinol a particularly advantageous alternative to steel. In fact, the superelasticity of nickel titanium is between 10 to 30 times the elasticity of normal metals like steel.
Many of us know nickel titanium from our flexible prescription eyeglass frames. The material allows frames to easily return to their original shape after being bent in any direction. Nickel titanium's uses are extremely varied, with applications that range from medicine to heat engines, lifting devices and even novelty toys—and now, earthquake engineering.
To assess the performance of nickel-titanium reinforced concrete bridges, the researchers analyzed three types of bridge columns: traditional steel and concrete, nickel titanium and concrete, and nickel titanium and engineered cementitious composites (ECC), which include cement, sand, water, fiber and chemicals. First, they modeled and tested the columns in OpenSEES, an earthquake simulation program developed at the University of California, Berkeley. Finally, they assembled and tested the columns on the UNR NEES shake table.
To strengthen the concrete and prevent immediate failure in an earthquake, the researchers used the shake tables to test glass and carbon fiber-reinforced polymer composites. Both composites substantially enhanced the reinforcing properties of concrete and the columns resisted strong earthquake forces with minor damage.
The results of both the modeling and shake table tests were extremely promising. The nickel titanium/ECC bridge columns outperformed the traditional steel and concrete bridge columns on all levels, limiting the amount of damage that the bridge would sustain under strong earthquakes.
While the initial cost of a typical bridge made of nickel titanium and ECC would be about 3 percent higher than the cost of a conventional bridge, the bridge's lifetime cost would decrease. Not only would the bridge require less repair, it would also be serviceable in the event of moderate and strong earthquakes. As a result, following a strong earthquake, the bridge would remain open to emergency vehicles and other traffic.

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