Structural behavior of precast concrete wall panels due to dynamic load: A review

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  • Structural behavior of precast concrete wall panels due to dynamic load: A review

    Precio : Gratis

    Publicado por : dnfsdd814

    Publicado en : 27-10-21

    Ubicación : Albacete

    Visitas : 25



    Structural behavior of precast concrete wall panels due to dynamic load: A review

    Structural behavior of precast concrete wall panels due to dynamic load: A review

        The rapid population growth and urbanization have made a massive demand for the shelter

    and construction materials. Masonry walls are the major component in the housing sector and

    it has brittle characteristics and exhibit poor performance against the uncertain loads.

    Further, the structure requires heavier sections for carrying the dead weight of masonry

    walls. The present investigations are carried out to develop a simple, lightweight and cost

    effective technology for replacing the existing wall systems. The lightweight concrete is

    developed for the construction of

    cement wall panel
    . The EPS (Expanded Polystyrene) beads of 3 mm diameter size are

    mixed with concrete and developed a lightweight concrete with a density 9 kN/m3. The

    lightweight sandwich panel is cast with a lightweight concrete inner core and ferrocement

    outer skins. This lightweight wall panel is tested for in-plane compression loading. A

    nonlinear finite element analysis with damaged plasticity model is carried out with both

    material and geometrical nonlinearities. The experimental and analytical results were

    compared. The finite element study predicted the ultimate load carrying capacity of the

    sandwich panel with reasonable accuracy. The present study showed that the lightweight

    concrete is well suitable for the lightweight sandwich wall panels.
        Architectural precast concrete wall panels that act as loadbearing elements in a

    building are both a structurally efficient and economical means o f transferring floor and

    roof loads through the structure  and into the foundation. In many cases, this

    integration can also simplify construction and reduce costs. This article presents the many

    benefit s that ca n be derived from using loadbearing architectural precast concrete walls

    in buildings. Discussed herein are the various shapes and sizes of wall pane ls, major

    design considerations, and when loadbearing or shear wall units should be the  first

    design choice. The role o f connections, shear walls, and the use of precast concrete as

    forms for cast-in-place concrete is explained. In general, the design methods and

    techniques presented in  this article apply to buildings in both seismic and non-

    seismic areas. The latter part of this article shows how these design principles can be

    applied in practice in a variety of buildings. These examples illustrate the use of window

    wall panels, spandrels, and solid or sandwich wall panels as the loadbearing wall members.

    When all the advantages of using architectural precast concrete as loadbearing walls are

    added up, it  makes good sense to use this structural form in building

    applications. 
        An experimental study has been carried out to determine the strength and behaviour of

    bamboo-reinforced concrete wood texture cement wall panel under one-way in-plane

    action. Three full-scale bamboo-reinforced concrete wall panels were tested to fail under a

    uniformly distributed load applied at an eccentricity of t/6. Slenderness ratio of all wall

    panels was kept constant as 25 with varying aspect ratio and thinness ratio. The influence

    of aspect ratio and thinness ratio on the ultimate strength and behaviour of wall panel was

    studied. The aspect ratio of wall panels considered includes 1, 1.204 and 1.515, and

    thinness ratio of wall panels includes 16.5, 20.75 and 25. Based on the study, an empirical

    equation for predicting the ultimate load of bamboo-reinforced concrete wall panel was

    proposed.
        The effect of the earthquake resulted in the destruction of infrastructure, especially

    residential buildings. The construction of decent housing with an adequate level of

    security is a demand. Generally, the most severe damage when an earthquake occurs is wall

    collapse of the houses. The precast panel wall is an alternative solution in answering the

    needs of post-earthquake housing development, because of the fast construction time and

    high calculation accuracy. The behavior of structural precast concrete



    split rock surface wall panels
    designed improperly instead of following the standard

    or regulations will likely encounter a poor performance during an earthquake compared to

    those designed in accordance with the standards. The purpose of the present study is to

    compile the findings from previous studies of precast concrete panel walls, especially

    their performances in handling earthquake load. It reveals that the stability, especially

    in ductility, affects the performance of precast concrete panel walls. In this study, the

    walls of precast concrete panels are made in half scale and given dynamic loads to simulate

    earthquake forces. This review is expected to provide guideline of similar subsequent

    research.
        It’s no wonder demand for precast is rising, especially considering the numerous

    benefits structural precast panels offer — from quick installation to fire resistance.
        1. Thermal insulation
        All elements of a well-engineered structural precast panel work together to provide a

    high level of insulation. Manufacturers often use a combination of concrete and EPS foam

    that maximizes the foam in the concrete piece, increasing insulation capabilities. A

    building constructed of structural precast panels may reduce energy consumption by as much

    as 30%.
        2. Sustainable materials
        Quite simply, a building made with structural precast panels will consume less energy,

    but an idea that should be at the heart of any sustainability conversation is product life.

    The use of concrete dates back to Roman times and its durability is still on display all

    across Europe. That raw, ancient building material has remained virtually unchanged for

    thousands of years. Many of the materials used in precast concrete are, as a rule, locally

    sourced, including the cement, the coarse and fine aggregates, and the steel.
        3. Long-term viability and flexibility
        Structural precast allows for a very modular building envelope. As business

    requirements change and needs evolve, an existing precast building has the flexibility to

    be expanded and modified. With structural precast concrete panels, you can add or remove

    pedestrian doors and dock doors, incorporate daylighting options, and even remove 75% of a

    wall. And due to its modular design, total repurposing of a precast building is entirely

    possible; churches can become car dealerships, warehouses can become micro-breweries… the

    options are only limited by a property owner’s imagination.
        4. Quick installation
        Speed is a critical hallmark of structural precast construction. “With precast panels,

    you can establish a larger completed footprint in a shorter amount of time,” says George

    Miks, director of engineering.“If you think of a masonry wall, what they send out to the

    site are a bunch of blocks that have to be assembled and constructed out in the field.”

    When structural precast panels arrive at a job site, the pieces are ready to install. If

    things go smoothly out in the field, an experienced crew can install 20 to 30, 12-foot

    panels in a day.
        5. Load-bearing capabilities and wind resistance
        Structural precast concrete panels are comprised of high-strength concrete and

    prestressed steel strand. It’s relatively routine for precast concrete wall panels have a

    compressive strength of approximately 7,000 PSI. You can apply loads in excess of 100,000

    pounds to the panels, Miks says. “When you build steel buildings, for instance, you have

    to put up perimeter beams and columns and then put steel skin against it. All of that steel

    has to support those enclosure panels,” Miks says. “With a structural precast wall

    system, you don’t need any of those perimeter beams and columns. You can just tip up the

    panel and have the roof steel members themselves attach to the precast. That also means you

    ’ll be spending less on steel.” Precast also stands up to Mother Nature’s wrath,

    shrugging off tornadoes, flying projectiles and winds up to 250 miles per hour.
        6. Fire and sound ratings
        Concrete is obviously an effective barrier for fire; it simply doesn’t burn well.

    Precast concrete thin cement rammed earth wall panels are capable of providing

    a two- to four-hour fire rating. Precast walls also stay intact even in hot chemical fires.

    Warehouses often use precast wall panels as dividers to protect goods on the other side of

    fire-prone areas. “The more delay you can create from one side to the other, the better

    chance of getting people out safely without incident and also the higher probability of

    protecting goods and services,” Miks says.
        Constructing a commercial structure is a huge undertaking and a significant investment.

    Whether you’re charged with the growth of a company, serving your community or building a

    legacy of your own, precast construction is a solid, responsible option said Miks.
        In this paper, an optimization-based design model of precast concrete

    cement rustic decoration wall panels for a building facade is presented.

    The key concept is an integrated model that can concurrently handle all of the related

    design and construction disciplines in the decision making process. The integrated model is

    decomposed hierarchically into several subproblems, thus a multilevel multiobjective

    optimization problem is obtained. Besides the multilevel aspect, the model presented can

    also handle knowledge-based requirements which are in general difficult to deal with by

    conventional hill-climbing optimization schemes. A solution procedure to solve this model

    is developed and applied to an example of PCWP for a four-story building facade.

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