Typical Engineer Story

  Image by https://rakanjayahardware.com/ S caffolding, falsework, shoring, bracing, and underpinning are just a few of the many examples of temporary structures that are commonly required in construction projects. The provision of structural support, the guaranteeing of worker safety, and the facilitation of the construction process are all important functions in building projects. Temporary structures that are either inadequately built or incorrectly installed have the potential to fail catastrophically, which may result in the destruction of property, personal injury, or even death. In this article, we will discuss the best procedures for designing and putting up temporary structures on construction sites. Design Principles Initially, the protection of everyone involved in the construction process and the general public should be the focus of every design. When thinking about safety, it's important to keep in mind things like how stable the structure is, how reliable the materia

Image by  Residential Slope Stabilization | South Hadley, MA (wellnesscapes.com) In geotechnical engineering, the method of slices is a foundational technique for analysing the stability of slopes. The factor of safety is determined by slicing the soil mass along a potential failure surface into a series of vertical slices and calculating the forces operating on each slice. The factor of safety (FS) quantifies the margin of safety against slope failure. It is the ratio between the shear strength and the shear stress necessary to maintain equilibrium. The process of slicing involves three essential steps: The failure surface is a hypothetical surface along which the soil material may slide as a result of external forces like gravity or seepage. The failure surface is selected based on engineering judgement and field observations. Division of the soil mass into segments: The soil mass is divided into equal or variable-width vertical slices. The size and number of slices are determined by

Image by beodom.com Geotechnical engineers may encounter a variety of obstacles when constructing ground-floor foundations in regions with elevated water tables. If the soil is inundated with water due to high water levels, the slab may experience settling, uplift, and buckling. This article discusses the steps geotechnical engineers can take to resolve these issues while ensuring the stability and durability of ground-level structures in such circumstances. To address the difficulties posed by high water tables, it is necessary to conduct a comprehensive site evaluation. Identifying the soil type and its properties, such as unit weight (), coefficient of permeability (k), and compressibility (Cc), is required. Determine the water table level and any other geological or soil conditions that may effect the stability of the slab. To determine the most effective remediation strategy, it is necessary to have a thorough understanding of all site conditions. The next step, following a thorou

  Malaysia has been experiencing significant growth in the construction industry over the past few years because of the development of massive infrastructure projects, commercial buildings, and residential properties across the country. Nevertheless, the recent development of BIM in the Malaysian building industry has further accelerated the progress in the sector. A digital tool that enables architects, contractors, engineers and owners to work harmoniously on a project, generating a virtual visual of the building, Building Information Modelling (BIM) has become increasingly prevalent in the industry. It permits the production of a three-dimensional representation of the building’s design and helps to avoid expensive and time-consuming rework. BIM involves creating and managing digital representations of buildings’ physical and functional characteristics. This is a cooperative approach that allows designers, technicians, builders, and proprietors to collaborate to create a comprehensi

Image by https://malaysiagazette.com/ As a geotechnical engineer, determining the correct factor of safety (FoS) for a rock slope is essential for ensuring its stability. FoS is a measure of the slope's resistance to forces acting upon it and is calculated by comparing the slope's resistance to forces acting upon it. When designing and evaluating rock slopes, geotechnical engineers take into account a number of factors, including the geology and geomorphology of the slope, the properties of the rock mass, and the potential for degradation and erosion. Therefore, engineers frequently collaborate with geologists to produce a more accurate representation of the slope by combining their knowledge and judgement. The strength and deformation properties of the rock mass have a significant effect on the FoS of a rock slope. These two parameters have a substantial effect on the FoS. There are a number of methods for determining these properties, including laboratory testing and in-situ

When I originally considered taking the Professional Competency Examination (PCE), I wasn't sure if it was the best choice for me because of the vast syllabus covered.  The list goes on. PCE is Malaysia's second-tier examination for professional qualification to become a registered Professional Engineer With a Practising Certificate. The test consists of two examinations, Common Paper and Technical Paper, each of which lasts around three hours. However, if you believe that your years of experience will benefit you in this exam, think again. Unlike the first tier, which emphasises accumulated experience and report preparation, this time you must thoroughly research the topics — similar to the college level of education you had — and come up with a good answer for the multiple-choice questions and essays. In contrast to undergraduate exams, which are presented in several papers throughout the semester, these exams are delivered in two papers and represent a considerable differenc

    Image by Freepik Concerns have been voiced regarding potential employment losses in the creative sector due to the rising reliance on artificial intelligence (AI). While it is true that some employment may be replaced by automation, it is crucial to note that not all creative positions are at risk of being mechanised. Jobs that involve human creativity and intuition are unlikely to be replaced by computers anytime soon due to the nature of creative activities that AI cannot imitate. As long as unique and original works that appeal to human desires and needs are produced, there will be a demand for creative jobs in the future. As long as people continue to create important works of art, there will be a viable and thriving creative sector. Businesses must adapt to changing market conditions by adopting cutting-edge technologies and software into their workflows. This will allow them to remain competitive and respond rapidly to market changes. Companies that lag behind their competito

With the introduction of artificial intelligence (AI) in civil engineering, some tasks can be automated to improve efficiency and accuracy while also benefiting the environment. Although technology will not be able to replace human employees, its function is projected to expand as machines become more advanced. AI is anticipated to play a big role in many everyday applications in the future, from self-driving cars to precision agriculture. Project management is one area in civil engineering where AI can have a substantial impact. Engineers must consider numerous critical elements when interpreting complicated designs in building projects, including work sequence and time. This can be difficult for people to keep track of, resulting in costly errors and delays. Engineers can avoid these issues by utilising AI technologies to monitor and control construction projects. Automated monitoring systems can be set to detect possible delays and other issues early, allowing them to be corrected b