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Vehicular Impact Resistance of Highway Bridge Seismically Designed UHPC Pier
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Journal of Steel Structures & Construction

ISSN: 2472-0437

Open Access

Commentary - (2021) Volume 7, Issue 10

Vehicular Impact Resistance of Highway Bridge Seismically Designed UHPC Pier

Sang Whan*
*Correspondence: Sang Whan, Hanyang University, Department of Architectural Engineering, Seoul, Republic of Korea, Email:
Hanyang University, Department of Architectural Engineering, Seoul, Republic of Korea

Received: 01-Nov-2021 Published: 23-Nov-2021
Citation: Sang Whan. "Vehicular Impact Resistance of Highway Bridge Seismically Designed UHPC Pier". J SSC (2021) 7:10.
Copyright: © 2021 Whan S. This is an open-access article distributed under the terms of the creative commons attribution license which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited

Description

Seismic design is a vital process of structural analysis while designing a building, which is subjected to Earthquake ground motions, such that the facility continues to function and serve its purpose even after an Earthquake. Seismic Engineering has evolved over a period of time, the complexity of analysis which used to contain numerous iterations of formulas have now been automated with tools like ETABS, STAAD. Pro, ROBOT, TEKLA and others. These tools results in advantageous outcomes including but not limited to safe, stable & durable structure along with optimization of design & cost-efficient structures. Hospital & Educational Buildings are special structures with high importance factor ranging around 25-50% analysis score than the residential or commercial structures.  different types of structural systems viz., seismic isolation system, energy dissipation system and active control systems etc., which enhances the seismic behavior of a building by dissipating the lateral forces without damaging the structural elements . The development of new structural systems and devices will proliferate the non-traditional civil engineering materials and techniques. By adopting such advanced system approaches based on dynamic analysis gives better representation of the behavior when simulated for seismic conditions.

Stiffness and strength

When designing earthquake-resistant buildings, safety professionals recommend adequate vertical and lateral stiffness and strength. This characteristic refers to the movement of the building when pushed in lateral directions. Safety professionals and building designers want the building to move equally so as to dissipate the energy without placing too much force on one side or another. If a building is irregular, then weaknesses will become apparent when the building sways. The weakness will compromise, and the structure will see concentrated damage which compromises the structure as a whole . A stable foundation is a major characteristic of building a large structure regardless of natural disaster risks. It is critical for a building’s long-term survival, and a stronger foundation is necessary to resist an earthquake powerful force. Different areas have unique foundational characteristics that define how a structure’s base needs to be reinforced. Professionals have to closely observe how the ground reacts and moves before building. Buildings designed to withstand violent earthquakes have deep foundations and driven piles. To stabilize these drastic measures, the foundations are connected so they move as a unit

Continuous load path

Tying into the stable foundation characteristic, structural and nonstructural components of a building need to be interconnected so inertial forces dissipate. Multiple points of strengths and redundancies share the force instead of the quake splitting the foundation apart . This is the continuous load path characteristic that safety professionals, architects, and engineers must remain wary of during design. If the structure is not comprehensively tied together, components will move independently, and collapse will be imminent. The continuous load path is the earthquake’s journey through the building laterally and vertically. It is vital the path is intact or else it won’t be able to dissipate an earthquake’s powerful shudders . Earthquakes happen less frequently than other natural disasters but building earthquake-resistant buildings protects against all-natural disasters. Safety professionals keep people’s safety a priority when researching and developing protective strategies for structural integrity. Due to the amount of synergy needed to develop earthquake-resistant building provisions, safety professionals work closely with other fields . They have to appreciate multiple factors they may not be experts in and communicate with other professionals to find the most effective solutions.

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