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The importance of geotechnics in construction

Updated: Feb 13


GEOTECHNICS IN CONSTRUCTION


The importance of geotechnics in construction is crucial, as its proper application can prevent catastrophic failures, reduce the risk of harm to people and property, and minimize the environmental impact of construction.


Construction can affect soil, water quality, biodiversity, and other aspects of the environment. The construction technique depends largely on the characteristics of the soil and geological materials present at the construction site.


Geotechnics is essential for assessing environmental impacts, assessing environmental risks associated with construction, and developing measures to minimize the environmental impact of construction.


It also helps determine whether deep or shallow foundation techniques should be used, whether piles or retaining walls are needed, and whether soil stabilization techniques should be implemented to reduce the risk of landslides or settlements.


Geotechnics evaluates soil quality and its ability to support loads, identifying any weaknesses or deficiencies that may affect the stability of the structure. In addition, it deals with the identification and evaluation of geotechnical risks, such as landslides, erosion, settlements, and other problems that may arise at the construction site.


Therefore, it is essential that civil engineers and other professionals involved in construction understand the importance of geotechnics and work collaboratively with geotechnical engineers to ensure that appropriate measures are taken to ensure the safety and stability of construction structures.


DAARWIN is a web platform that connects and centralizes geotechnical data throughout the project lifecycle. Our machine learning algorithm makes predictive models more accurate for diagnosing oversized designs and anticipating unforeseen events. This technology minimizes risk and maximizes sustainability and profitability of your construction project.


Our software overcomes the limitations of laboratory and in-situ tests by using historical data and real-time inverse analysis, a methodology that compares geotechnical instrumentation data (such as conventional topography, inclinometers, incremental extensometers, piezometers, etc.) with a predictive numerical model. In this way, a much more precise and reliable representation of the behavior of the ground is obtained. geotechnical, software engineer, geotechnical engineering software, construction AI, civil engineering software

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