Sterling Engineering’s Post

🚀 Join Our Team of Technical Mentors! 🚀 Are you a seasoned professional in Electrical Engineering, Engineering and Information Technology, or the Energy sector? We're on the hunt for experts like you to join The Transformation Legacy Mentor Network and make an impact! Our service offerings span a wide range of industries, and we're looking for technical mentors who can guide and inspire the next generation of talent. Here's where your expertise can shine: Electrical Engineering: AC & DC electrical motors Submersible pumps Traction motors Gear motors Conveyer belt motors Vibrator motors Lift motors and Air compressors Power Engineering and Networks Control and Instrumentation Reliability Engineering and Energy Management Supplying Electrical Consumables Automation projects System integration Panel and MCC manufacturing Valve repair, reconditioning, and service solutions Generator installations and service Air conditioner installation and service Engineering and Information Technology: Vehicle tracking Fleet management solutions Asset tracking Fuel consumption monitoring Mobile tracking Personal tracking Energy sector: Recycling Waste Management If you're passionate about sharing your knowledge, guiding the next generation, and being part of an innovative team, we want to hear from you! Ready to embark on this exciting journey? Reach out to us today! 💡🌟 #TheTransformationLegacy #Entrepreneur #EntrepreneurSA #LeaveALegacy #PersonalDevelopement #mentorship #enterprisedevelopment #smallbusinessgrowth #entrepreneurship #Levelup #EntrepreneurLife #SuccessMindset #SmallBusinessLove #MentorshipOpportunity #JoinOurTeam #TechnicalMentors #Engineering #Technology #EnergySector #Heritagemonth

Back to learning process, there is always new opportunity to learn and growth..change of field of work make a lot of new thing to learn.. #GE #multilin #engineer #technical #electrical

I have over 6 years of experience in Power System Studies and have worked on solving problems related to Power Engineering in industrial plants. I have a wide range of skills and expertise in various aspects of power systems, which makes me a valuable asset for any project related to power system analysis and modelling. Some of the examples of your projects could include: • Conducting Grid Impact Studies for large-scale industrial plants to ensure the reliability and stability of the power system. • Developing dynamic models in DigSilent PowerFactory for various power system components such as AVR, PSS, UEL, OEL, Governor, etc., to simulate the system's behaviour under different operating conditions and disturbances. • Conducting RMS simulations to analyse the system's response to different types of faults and disturbances. • Performing harmonic analysis to identify and mitigate harmonic distortion in the power system. • Conducting Transfer Capacity analysis (P-V, Q-V) to assess the system's capacity to transfer power between different regions. • Conducting Relay Protection Coordination studies to ensure the proper coordination of protective relays in the power system. • Developing models in Matlab to simulate and analyse the system's behaviour under different operating conditions. • Solving complex problems related to Power Systems such as fluctuations in power system, vibration of engines, etc. • Conducting DigSilent courses to train power system engineers and technicians on power system analysis and modelling. • Developing models in ETAP to simulate and analyse the behaviour of power systems under different operating conditions. • Conducting Arc Flash Studies to assess the hazards associated with electrical arcs in the power system. • Conducting Relay Protection Coordination studies to ensure the proper coordination of protective relays in the power system. • Conducting G99 studies to ensure the effective integration of renewable energy sources into the power system. My expertise in these areas can help clients identify potential issues in their power systems and develop effective solutions to mitigate them. With licensed software such as ETAP 2022 with Grid code study module and DigSilent 2022, I can provide accurate and reliable results to your clients. https://lnkd.in/ebrAspha

#hiring Project & process engineer PCAM, Brussels, Belgium, fulltime #jobs #jobseekers #careers #Brusselsjobs #Brusselsjobs #ManufacturingOperations Apply: https://lnkd.in/d3NWMvZZ Belgium - OlenRechargeable Battery MaterialsEngineering & Technology, Process & Product DevelopmentPosted on 02-06-2023About UmicoreReducing harmful vehicle emissions. Powering the cars of the future. Giving new life to used metals. We are the leading circular materials technology company fulfilling its mission to create materials for a better life. With ambitions like this, imagine what you could do?Rechargeable Battery Materials We are all on the move. Umicore's rechargeable battery materials give people autonomy and connectivity. We are a pioneer in battery materials that give added range and performance to electric vehicles. Our materials also ensure longer battery life for portable electronics. To enable our customers to produce even better performing batteries we cannot stand still. We need to find new ways to do things, discover new solutions and develop new ideas. Which is where you come in.What you will be doingWe are currently looking for an exceptionally skilled and experienced project Engineer specializing in mechanical, automation, or related engineering fields to join our dynamic Engineering Department. As part of our team, you will play a crucial role in project engineering, specifically in the concept and basic design phase of the manufacturing process for precursor cathode materials. Your extensive knowledge in process engineering, automation, equipment design, and project management will be pivotal in developing innovative solutions and ensuring the successful implementation of the manufacturing process.Responsibilities:Project Conceptualization: Take the lead in conceptualizing and developing the manufacturing process for precursor cathode materials. Consider various factors such as material characteristics, process flow, equipment selection, and safety considerations.Basic Design Development: Create the basic design of the manufacturing process, including process flow diagrams, equipment specifications, material handling systems, utilities requirements, and control strategies. Automation and Control Systems: Collaborate with automation engineers to design and implement automation and control systems for the precursor cathode materials manufacturing process. This involves working with PLCs, HMIs, and SCADA systems. Equipment Selection and Design:Identify and choose suitable equipment and machinery for the manufacturing process. Collaborate with equipment suppliers, mechanical engineers, and vendors to optimize equipment specifications and design. Process Optimization: Identify opportunities for process optimization and efficiency improvement. Take into account factors such as yield, quality, cost, and environmental impact.Propose innovative solutions and modifications to enhance

🧑🔧💡Electrical engineering is a field that combines innovation, sustainability, and technology. Your work contributes to improving the country's energy sector. Seeing your work, people gain confidence and hope that we are moving towards a better and prosperous future. In this field, your creativity, problem-solving skills, and dedication will lead you to new heights. Never underestimate your passion, and always see new challenges as opportunities to improve in your work. With your hard work and dedication, you can definitely motivate yourself and others.🧑🔧💡🧑🏻🔧

Hello LinkedIn network, I am excited to share my journey as a Maintenance Engineer with over 8 years of experience in proactive maintenance, industrial equipment management, and operational performance optimization. Here's a glimpse of my professional background and the skills I've honed over the years: 🔧 Expertise in Maintenance and Engineering: Managed preventive and corrective maintenance for complex mechanical, electrical, and hydraulic systems, ensuring minimal downtime and high efficiency. Implemented innovative solutions to complex maintenance problems, leading to a 30% reduction in equipment breakdowns and a 20% increase in production efficiency. 📊 Data-Driven Optimization: Utilized data analysis to identify and implement improvements in equipment performance, resulting in optimized operations and cost savings. Successfully introduced an automated stock management system, reducing maintenance costs by 15% and improving the availability of spare parts. 👥 Leadership and Team Coordination: Coordinated and trained teams on maintenance and safety procedures, fostering a culture of safety and continuous improvement. Led cross-functional teams in managing bids and proposals, increasing the success rate of bids by 25%. 💡 Continuous Learning and Adaptability: Committed to continuous professional development with certifications in PLC programming, numerical control programming, and electrical safety for medium voltage substations. Adaptable and able to manage stress effectively, ensuring productivity even in challenging situations. I am always looking to connect with like-minded professionals and explore opportunities to leverage my skills and experience to drive operational excellence. Feel free to reach out if you are interested in discussing potential collaborations or sharing insights on maintenance and engineering best practices. #MaintenanceEngineering #IndustrialEquipment #OperationalExcellence #TeamLeadership #ContinuousImprovement

Instrumentation and control engineering (ICE) is a branch of engineering that studies the measurement and control of process variables, and the design and implementation of systems that incorporate them. Process variables include pressure, temperature, humidity, flow, pH, force and speed. ICE combines two branches of engineering. Instrumentation engineering is the science of the measurement and control of process variables within a production or manufacturing area.[1] Meanwhile, control engineering, also called control systems engineering, is the engineering discipline that applies control theory to design systems with desired behaviors. Control engineers are responsible for the research, design, and development of control devices and systems, typically in manufacturing facilities and process plants. Control methods employ sensors to measure the output variable of the device and provide feedback to the controller so that it can make corrections toward desired performance. Automatic control manages a device without the need of human inputs for correction, such as cruise control for regulating a car's speed. Control systems engineering activities are multi-disciplinary in nature. They focus on the implementation of control systems, mainly derived by mathematical modeling. Because instrumentation and control play a significant role in gathering information from a system and changing its parameters, they are a key part of control loops. Specializations ice include industrial instrumentation, system dynamics, process control, and control systems. Additionally, technological knowledge, particularly in computer systems, is essential to the job of an instrumentation and control engineer; important technology-related topics include human–computer interaction, programmable logic controllers, and SCADA. The tasks center around designing, developing, maintaining and managing control systems. The goals of the work of an instrumentation and control engineer are to maximize: Productivity Optimization Stability Reliability Safety Continuity

Hello connections, 🚀 Series-1 (Post 1) 🚀 (Mandatory rocket emoji) I’m thrilled to announce the start of a new series on Process Engineering! Why did I decide to kick off this series, especially at 1 in the night? I don't know I am not even a process engineer. Whether you're a seasoned professional or a curious newbie like me, I hope we can learn together. I’m counting on my incredible network of process engineers to share their insights and add value to these discussions. Let’s make this a collaborative journey! So, what exactly is process engineering? Process engineering is all about designing, optimizing, controlling, and managing chemical, physical, and biological processes to convert raw materials into valuable products. Here’s a quick rundown of the key activities: 1. Design: Crafting efficient and effective processes using process flow diagrams (PFDs) and piping and instrumentation diagrams (P&IDs). Selecting the right equipment and technology is crucial here. 🔧 2. Optimization: Enhancing processes to boost efficiency, cut costs, increase yields, and improve product quality. This often involves process modeling and simulation. 💡 3. Control: Implementing systems to monitor and regulate process variables, ensuring operations stay within desired parameters and meet safety and quality standards. ⚙️ 4. Scale-up: Transitioning processes from laboratory or pilot scale to full industrial scale, tackling challenges related to economics, safety, and practical feasibility. 📈 5. Safety and Environmental Management: Ensuring processes comply with health, safety, and environmental regulations. This includes conducting risk assessments and implementing measures to mitigate potential hazards. 🌱 6. Sustainability: Developing processes that minimize environmental impact, enhance resource efficiency, and promote sustainable practices. 🌍 Process engineers are pivotal in industries such as chemicals, petrochemicals, pharmaceuticals, food and beverage, oil and gas, water treatment, and renewable energy. Their mission is to design and manage processes that are safe, efficient, cost-effective, and environmentally friendly. 🌐 I’m excited to learn and share more about this fascinating field. Stay tuned for more posts in this series! Let’s spread the knowledge! ✨ #ProcessEngineering #EPC #Sustainability #Innovation #Optimization #Engineering #LearningJourney #Collaboration ---

I have successfully completed Professional Certificate of Competency in Instrumentation, Automation and Process Control. I appreciate the support and mentorship from Eng Tinashe Rueben Chireshe , Eng Munyaradzi Gutsa, Emmanuel Pindura ,Eng Chinelo Ndunaka and Ing. Bright Ofosu Appiah, PE-GhIE. I believe I'll benefit much from the course as I pursue my engineering career. I strongly recommend courses offered by Engineering Institute of Technology. #EIT #instrumentationandcontrol #automationsolutions Learning never exhausts the mind

Have you ever wondered how do industrial plants ensure the products we use every day are made with the high standards? Industrial instrumentation is a branch of engineering that selects, installs, maintains and calibrates devices that measure, control and monitor physical processes in various industries. Sensors, transducers, controllers, actuators, indicators, recorders and such are industrial instrumentation devices used for different purposes. These devices can measure temperature, pressure, flow, level, pH, humidity, vibration, speed, force, torque, etc.   Different process measurements are relevant with many parameters within industries. By utilizing industrial instrumentation, the goal is to improve the efficiency, safety, quality and reliability of processes by providing accurate and timely information and feedback. Industrial instrumentation requires knowledge of mathematics, chemistry, physics, electronics, mechanics, computer science and industry specific applications.   One example regarding the application of industrial instrumentation is manufacturing. For example, in a steel plant, instruments can monitor and regulate the blast furnace, the rolling mill, and/or the cooling system, all integral or separate. Another example could be in a dairy plant, to control the pasteurization, homogenization, and fermentation of milk, cheese, and/or yogurt.   In oil and gas, instruments are used to optimize the extraction, transportation, and refining of oil and gas, such as by measuring the level, flow, pressure, and temperature of wells, pipelines, and tanks. In relation, in chemical operations, it is vital measuring the pH, conductivity, viscosity, density, and concentration of reactants.   The challenge with instrumentation begins with selecting the appropriate technology for a specific application. There are many types of instruments available, each with its own range of measurement accuracy, sensitivity, and cost. Choosing the wrong instrument can lead to recurring malfunctions, failures, or inaccurate readings which will cancel out all benefits of business process improvement. So, selection is the most critical part of industrial instrumentation. Users or operators of the instruments may not have enough technical knowledge or training to interpret the readings correctly, or to troubleshoot the problems that may arise. Adapting to the changing technologies, standards and new technologies, such as wireless, or smart instruments, offer new possibilities and challenges for the instrumentation engineers. There are also problems associated with noise, interference, drift, calibration errors, or environmental effects. The instruments have to communicate and interact with the process control systems, such as PLCs, DCSs, or SCADA, to provide feedback and control for the industrial processes. This requires the instrumentation engineers to have knowledge of the communication protocols, data formats, and software languages used by these systems.