Services

Structural Design

We approach every project not merely as a building, but as a lasting value for the future. By evaluating multiple design approaches, we develop innovative structural solutions that combine safety, efficiency, and sustainability.

Our engineering philosophy integrates aesthetics, technology, and environmental responsibility to create long-lasting, high-quality structures.

We provide structural design services in compliance with national and international standards across the following areas:

• High-Rise Buildings
• Residential Buildings
• Healthcare Facilities
• Educational Buildings
• Hotels
• Office & Commercial Buildings
• Industrial Facilities

At every project scale, we deliver value through reliable, sustainable, and contemporary engineering practices.

Performance-Based Design

Our structural design approach is centered on performance—understanding and predicting a building’s actual behavior. Our goal is not just to meet code requirements, but to design safe structures that exhibit controlled, predictable performance under seismic effects, with target levels of damage.

In evaluating existing structures’ earthquake safety and developing new specialized projects, we use national and international standards as a baseline, applying advanced engineering analyses to achieve project-specific performance goals.

For high-rise and complex structures, conventional code-based approaches may not always provide optimal engineering solutions. In these cases, we employ nonlinear analysis methods that reflect the building’s real behavior, shaping design decisions through numerical data and scientific methodology.

With our performance-based design approach:

• Seismic hazards and risk levels are defined for each project
• Target performance criteria are clearly established
• The building’s seismic behavior is modeled using nonlinear analysis techniques
• Pushover and Incremental Dynamic Analyses (IRSA) are used to verify system reliability

This ensures buildings are not only code-compliant but also designed to measurable, verifiable, and sustainable safety levels.

Seismic Response Spectrum for Racking Systems

Racking systems in industrial and logistics facilities are critical elements that behave as part of the structural system during earthquakes. Accurate assessment of their seismic performance is vital for facility safety and operational continuity.

In preparing the response spectrum, we consider regional seismic hazards, soil conditions, and building dynamic characteristics comprehensively. The goal is to provide project-specific, realistic seismic demands rather than relying on standard assumptions, ensuring safe and optimized racking system design.

Key steps include:

• Defining site-specific seismic hazard parameters
• Analyzing dynamic properties and story accelerations of the building
• Generating floor acceleration spectra as design inputs for racking systems
• Performing verifications in accordance with national and international performance standards

Our tailored response spectra prevent unnecessary cost increases while ensuring system stability and operational continuity during seismic events.

This approach frames engineering as risk management and sustainable operational safety, not just calculation.

Advanced Analysis and Numerical Modeling

Accurate structural decisions begin with accurate modeling. We place advanced analysis techniques and high-precision numerical modeling at the heart of our design process.

Acknowledging each structure’s unique dynamic characteristics, we evaluate load-bearing systems using realistic, project-specific models rather than idealized assumptions. For complex geometries, irregular systems, high-rise buildings, and specialized projects, we apply advanced analysis methods to fully understand structural behavior under seismic and environmental loads.

Key steps include:

• Linear and nonlinear analyses
• Time-history analyses
• Dynamic and modal analyses
• High-rise structural modeling
• Second-order effects and stability assessments

Techniques employed include.

Our objective is not merely to produce calculations, but to validate design decisions scientifically, reduce uncertainties, and make performance measurable. Numerical modeling allows early prediction of structural behavior, risk identification, and system optimization.

Advanced analysis enhances not only safety but also transparency, verifiability, and engineering depth.

Technical Competence

We define technical competence as the combination of knowledge, experience, analytical thinking, and engineering intuition. Every project merges theoretical foundations with field realities to produce practical, safe, and sustainable solutions.

By effectively utilizing advanced analysis, numerical modeling, and up-to-date engineering software, we predict structural behavior, identify risks early, and support design decisions with scientific data.

Core components of our technical competence include:

• Advanced analysis and modeling capabilities
• Mastery of national and international codes
• Performance-based design approach
• Material and system optimization
• Engineering precision in detailed solutions

Our aim is not just compliance with specifications but understanding real structural behavior to define the optimal load-bearing system.

Continuous improvement, research, and innovation drive our technical capabilities, converting complex problems into clear, actionable solutions. Technical competence is the foundation of trustworthy structures.

Project Discipline

Successful structural design requires more than technical knowledge—it demands robust project discipline. For us, project discipline means systematic thinking, transparent communication, and measurable quality standards throughout all stages.

We start every project with clear objectives, proper scheduling, and coordinated strategies. Integrated collaboration with architectural, mechanical, and electrical disciplines, combined with data-driven analysis for decision-making, ensures not only accurate engineering solutions but also manageable, sustainable project processes.

Our project discipline is guided by:

• Defining clear scope and performance targets
• Stepwise control and verification mechanisms
• Interdisciplinary coordination and integration
• Balancing time, cost, and quality
• Documentation and traceability culture

This approach minimizes uncertainty, anticipates risks, and maintains control even in complex projects.

For us, project discipline is not just meeting deadlines—it is creating a fully planned, supervised, and secure engineering process.