Design Engineer

Roles and responsibilities

• Proficient in creating control and protection drawings for various systems.
• Knowledgeable in various protection schemes, including busbar protection and FMS.
• Familiar with control schemes, including SAS architecture, hardware selection for SAS, AVR, and transformer paralleling.
• Experienced with different types of protection relays from major OEMs.
• Capable of preparing SLDs, protection block diagrams/PSLDs, interlocking logics, trip matrices, detailed schematics, and has basic knowledge of HV equipment.
• Able to coordinate with primary equipment vendor, Manufacturing and FAT and commissioning team.
• Skilled in preparing CT/VT adequacy checks, AC/DC load calculations, and availability/reliability calculations.
• Competent in reviewing various vendor drawings during the execution stage.
• Knowledgeable about relevant international standards such as IEC and ANSI.
• Able to prepare drawings according to project requirements.
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Your Qualifications and Skills – Digital and Solid!

• Expected degree qualification – Bachelor of Engineering from recognized university.
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• Relevant year of experience- 4 to 8
• Knowledge of expertise- Protection and Control System
• Any required certification- Any Certification or training related to Protection and Control systems
• Personal skills- Strong interpersonal and communication skills, Diligent, team player& self-motivated
• Safety standards: Ensuring that designs meet industry-specific safety standards, regulations, and certifications (e.g., CE, UL, ISO).
• Environmental considerations: Designing products that comply with environmental regulations, focusing on sustainability, recycling, energy efficiency, and minimizing waste.
• Quality assurance: Implementing quality control processes and ensuring designs adhere to the required standards and specifications.
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Desired candidate profile

1. Product Design and Development

• Conceptualization: Creating initial concepts or ideas for products, taking into consideration customer needs, functionality, and aesthetics.
• Design refinement: Iterating designs based on feedback and performance testing, ensuring the product is optimized for its intended use.
• Prototyping: Developing physical or digital prototypes to validate design concepts and make adjustments before final production.
• Material selection: Choosing appropriate materials for the design, considering factors like strength, weight, durability, and cost.
• User experience: Ensuring the design is user-friendly, intuitive, and efficient for the end user.

2. CAD (Computer-Aided Design) Proficiency

• CAD software: Mastery in tools like AutoCAD, SolidWorks, CATIA, Revit, Fusion 360, or Inventor to create detailed 2D and 3D models of designs.
• 3D modeling: Using CAD tools to create realistic 3D representations of products to visualize and test designs before manufacturing.
• Design documentation: Creating technical drawings, blueprints, and assembly instructions to communicate design intent to manufacturers, engineers, or production teams.

3. Engineering Analysis and Simulation

• Finite Element Analysis (FEA): Using simulation software to analyze the mechanical behavior of parts or assemblies, such as stress, strain, and thermal performance, ensuring the design will function as intended.
• Computational Fluid Dynamics (CFD): Simulating fluid flow or heat transfer for designs related to airflow, cooling, or energy systems.
• Tolerance analysis: Evaluating and defining acceptable limits for dimensional variations in the design to ensure manufacturability.
• Performance testing: Conducting physical or virtual tests to ensure that the design meets safety, functionality, and reliability standards.

4. Design for Manufacturability (DFM) and Assembly (DFA)

• Cost optimization: Designing products to be produced at the lowest possible cost while maintaining quality, performance, and durability.
• Assembly considerations: Creating designs that are easy to assemble and reduce the number of components or steps in the assembly process, improving efficiency.
• Manufacturing processes: Understanding various manufacturing techniques such as injection molding, CNC machining, additive manufacturing, and sheet metal forming to design products that are practical and feasible to produce.

5. Prototyping and Testing

• Rapid prototyping: Using methods like 3D printing, CNC machining, or casting to create prototypes quickly for testing and iteration.
• Functional testing: Ensuring prototypes meet functional requirements by testing them in real-world conditions or simulations.
• Iterative design: Refining designs based on prototype feedback and testing results, making improvements before full-scale production.