We are dedicated to providing comprehensive engineering services tailored to meet the diverse needs of our clients across various industries. With a team of experienced professionals and a commitment to excellence, we offer a wide range of services includes:

Pre-FEED (Pre-Front-End Engineering Design)

is the project's initial phase, where the basic concept is developed into a defined scope of work. It involves feasibility studies, preliminary engineering assessments, and conceptual designs to evaluate technical and economic viability. Key objectives include defining project goals, conceptualizing solutions, conducting feasibility studies, estimating costs and schedules, and identifying/mitigating risks. Pre-FEED sets the foundation for subsequent project stages by providing clarity on scope, requirements, and feasibility before detailed engineering phases commence.

Piping Engineering

Piping Material Specifications

Detailed Material Specifications: Developing comprehensive piping material specifications outlining the types of materials, grades, and standards required for various piping components, including pipes, fittings, and valves.

Material Selection Assistance: Assisting clients in selecting appropriate piping materials based on factors such as process conditions, corrosion resistance, and budget considerations.

Piping Bulk Material Estimation

Accurate Material Estimation: Providing accurate estimates of bulk materials required for piping systems, including pipes, fittings, flanges, and supports, to facilitate procurement and construction planning.

Cost Optimization: Optimizing material quantities and minimizing wastage to reduce project costs while ensuring sufficient materials are available for construction activities.

Pipe Stress Analysis (Dynamic & Static)

Comprehensive Stress Analysis: Conducting both dynamic and static pipe stress analysis to evaluate the structural integrity and performance of piping systems under various operating conditions, including thermal expansion, pressure fluctuations, and seismic loads.

Compliance with Standards: Performing stress analysis in accordance with industry standards such as ASME B31.1, ASME B31.3, ASME B31.4, and ASME B31.8 to ensure compliance with regulatory requirements.

Piping Design Specifications

Detailed Design Specifications: Developing detailed design specifications for piping systems, including pipe sizes, pressure ratings, wall thicknesses, and material specifications, to ensure safe and efficient operation.

Design Optimization: Optimizing piping designs to minimize pressure drops, reduce energy consumption, and enhance system performance while meeting project requirements and constraints.

3D Modeling

Advanced 3D Modeling: Creating detailed 3D models of piping systems using state-of-the-art modeling software, allowing for virtual visualization, clash detection, and coordination with other plant components and structures.

Visualization and Collaboration: Enhancing project visualization and communication by providing realistic 3D renderings and walkthroughs for design reviews and stakeholder presentations.

Plant Layout Design: Developing plant and piping layouts to optimize space utilization, facilitate equipment access, and ensure efficient routing of piping systems within the facility.

Isometrics Extraction: Generating isometric drawings and fabrication isometrics directly from 3D models to provide detailed fabrication and construction drawings for piping components.

Customized Support Design: Designing customized pipe supports, hangers, and restraints to ensure proper alignment, stability, and load-bearing capacity of piping systems, considering factors such as thermal expansion, seismic loads, and equipment layout.

FEED (Front-End Engineering Design)

FEED (Front-End Engineering Design) comes after Pre-FEED and involves detailed engineering and design work to create a comprehensive project plan. The project team refines conceptual designs, material/equipment selection, cost estimation/control, schedule development, and regulatory compliance. It serves as a bridge between conceptual and detailed engineering, supporting procurement, construction, and commissioning activities.

Mechanical Engineering

Mechanical Equipment Data Sheets

Comprehensive Data Sheets: Developing detailed data sheets for mechanical equipment, encompassing both static and rotating machinery, to provide essential information such as specifications, dimensions, performance criteria, and operational parameters.

Equipment Selection Assistance: Assisting clients in selecting the most suitable mechanical equipment for their projects based on technical requirements, budget considerations, and long-term operational needs.

Rotating Equipment Specifications

Detailed Specifications: Developing specifications for rotating equipment, including pumps, compressors, turbines, and motors, to ensure they meet the performance, reliability, and safety requirements of the project.

Performance Criteria Definition: Defining performance criteria such as flow rates, pressure ratings, and efficiency targets to guide the selection and procurement of rotating equipment.

Static Equipment Specifications

Precise Static Equipment Specs: Creating specifications for static equipment such as pressure vessels, heat exchangers, and storage tanks, outlining design parameters, materials of construction, and fabrication standards.

Compliance with Standards: Ensuring that static equipment specifications comply with industry codes and standards, including ASME, API, and ASTM requirements, to guarantee safety and regulatory compliance.

Rotating and Static Equipment Material Requisition

Detailed Material Requisition Documents: Generating comprehensive material requisition documents specifying the quantity, quality, and specifications of materials required for the procurement and fabrication of both rotating and static equipment.

Vendor Evaluation Support: Assisting clients in evaluating and selecting qualified vendors and suppliers to ensure the timely procurement of materials and equipment meeting project specifications and quality standards.

Technical Bid Evaluation

CAPEX vs OPEX Analysis: Conducting technical bid evaluations based on both capital expenditure (CAPEX) and operational expenditure (OPEX) considerations for rotating equipment, assessing factors such as initial investment costs, maintenance requirements, and lifecycle operating expenses.

Cost-Benefit Analysis: Performing cost-benefit analyses to compare alternative equipment options and recommend the most cost-effective solution that aligns with the client's project objectives and budget constraints.

Static Equipment Fabrication Drawings

Detailed Fabrication Drawings: Creating precise fabrication drawings for static equipment components, including vessels, columns, and tanks, to provide manufacturing instructions and ensure accurate fabrication according to design specifications.

Quality Assurance Documentation: Developing quality assurance plans and documentation to verify the integrity and compliance of fabricated static equipment with applicable standards and regulatory requirements.

Basic Engineering

Basic Engineering is the initial phase of the engineering design process where fundamental concepts and specifications of the project are established. It includer activities like process design, equipment sizing/selection, creating preliminary P&IDs, identifying utility requirements, and conducting preliminary hazard analysis. Basic engineering sets the foundation for detailed engineering phases by establishing key parameters and providing a framework for further design development and analysis.

Civil Engineering

Structural Calculation and Analysis

Structural Load Analysis: Conducting thorough analysis to determine the loads acting on structures and components, ensuring safety and stability.

Structural Design Optimization: Developing efficient and cost-effective structural designs that meet project requirements while minimizing material usage and construction costs.

Structural Integrity Assessment: Evaluating the integrity and performance of existing structures through advanced analysis techniques, such as finite element analysis (FEA) and computational fluid dynamics (CFD).

Structural Fabrication Drawings

Detailed Fabrication Drawings: Creating precise fabrication drawings that provide all necessary information for manufacturing and construction, including dimensions, materials, and assembly instructions.

Welding and Fabrication Specifications: Specifying welding procedures, materials, and quality requirements to ensure structural integrity and compliance with industry standards.

Quality Control Documentation: Developing quality control plans and documentation to verify the accuracy and integrity of fabricated structural components throughout the manufacturing process.

Static Equipment Fabrication Drawings

Detailed Fabrication Drawings: Creating precise fabrication drawings for static equipment components, including vessels, columns, and tanks, to provide manufacturing instructions and ensure accurate fabrication according to design specifications.

Quality Assurance Documentation: Developing quality assurance plans and documentation to verify the integrity and compliance of fabricated static equipment with applicable standards and regulatory requirements.

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