Building Simulation Studies for Energy Efficiency & Environmental Impact

Predict Performance Before You Build – Optimize Design with Advanced Simulation

Make informed decisions about your building design with our advanced simulation and modeling services. Using industry-leading software like EnergyPlus, eQUEST, DesignBuilder, and CFD tools, we analyze energy performance, daylighting, thermal comfort, and environmental impact before construction begins—saving you time, money, and ensuring optimal efficiency.

Our Expertise:

100+ simulation projects completed
BEE-certified energy auditors and ECBC Master Trainers
IGBC & LEED accredited professionals
Advanced software proficiency

What is Building Performance Simulation?

Building performance simulation is the use of computer software to create a virtual model of your building and predict how it will perform in real-world conditions. By simulating a full year of operation with actual weather data, we can:

Predict energy consumption before construction
Compare design alternatives quantitatively
Optimize building systems for efficiency
Demonstrate ECBC compliance through the Whole Building Performance Method
Achieve green building certifications (IGBC, LEED, GRIHA)
Identify problems early when changes are still cost-effective
Reduce risk by making data-driven decisions

Think of it as a “test drive” for your building—you can experiment with different designs, materials, and systems virtually before committing to expensive construction decisions.

Simulation studies in relation to Energy Efficiency and Environmental Impact in kolkata

Why Building Simulation is Essential

1. Avoid Costly Mistakes

Design changes during construction can cost 10-100 times more than changes during design. Simulation identifies potential issues early when fixes are cheap.

2. Optimize Performance

Simulation lets you test dozens of design options to find the most efficient combination of building orientation, envelope, systems, and controls.

3. Meet Code Requirements

ECBC compliance via the Whole Building Performance Method requires energy simulation. We ensure your model meets all code requirements.

4. Achieve Certification Goals

Green building certifications (IGBC, LEED, GRIHA) award significant points for energy performance. Our simulations help maximize your scores.

5. Make Data-Driven Decisions

Instead of guessing which HVAC system is best, simulation provides quantitative comparisons with energy consumption, costs, and payback periods.

6. Demonstrate ROI

Our reports show stakeholders exactly how much energy and money each design feature will save, making it easier to justify sustainable investments.

7. Comply with Regulations

Many states now require energy modeling for buildings above certain sizes. We keep you compliant with evolving regulations.

Our Simulation Services

1. Energy Modeling & Simulation

What We Model:

Building Envelope:

Wall assemblies and insulation
Roof construction and reflectivity
Window-to-wall ratios
Glazing properties (U-value, SHGC, VLT)
Shading devices and overhangs
Air infiltration rates

HVAC Systems:

Chilled water systems with chillers, pumps, cooling towers
VRF/VRV multi-split systems
Package and split AC units
Air handling units (AHU) and fan coil units (FCU)
Ventilation and outdoor air requirements
Economizers and heat recovery
Controls and setpoints

Lighting Systems:

Interior lighting power density
Lighting controls (occupancy sensors, daylight dimming)
Exterior lighting
Emergency lighting

Internal Loads:

Occupancy schedules
Equipment and plug loads
Process loads (for specialized facilities)
Domestic hot water systems

Renewable Energy:

Solar photovoltaic systems
Solar water heating
Wind turbines
Geothermal systems

Software We Use:

EnergyPlus: DOE’s flagship simulation engine, most accurate and detailed
eQUEST: Fast and widely used for code compliance and design analysis
DesignBuilder: EnergyPlus with intuitive 3D interface
TRACE 700/3D Plus: Trane’s comprehensive HVAC design and analysis tool
IES VE (Virtual Environment): Integrated suite for energy, daylighting, and CFD

Deliverables:

Baseline and proposed building energy models
Annual energy consumption by end-use (HVAC, lighting, equipment, hot water)
Monthly energy profiles
Peak demand analysis
Utility cost estimates (electricity, gas, diesel)
Energy Use Intensity (EUI) benchmarking
ECBC compliance documentation
Parametric analysis comparing design options
Comprehensive report with recommendations

Applications:

New building design optimization
Major renovation and retrofit planning
ECBC compliance demonstration
Green building certification (IGBC, LEED, GRIHA)
Energy conservation measure evaluation
Life cycle cost analysis

Typical Timeline: 2-4 weeks depending on building complexity Investment: ₹50,000-3,00,000 based on project size and detail

2. ECBC Compliance Modeling

The Energy Conservation Building Code (ECBC) requires commercial buildings with connected load ≥100 kW to meet minimum energy efficiency standards.

Compliance Paths:

Prescriptive Method: Meet all mandatory requirements plus requirements for each building system (envelope, HVAC, lighting, etc.)

Trade-Off Method: Trade off performance in one system for better performance in another while meeting overall targets

Whole Building Performance Method: Demonstrate through simulation that your proposed building uses less energy than a compliant baseline building

Our ECBC Modeling Services:

For New Buildings:

Baseline model per ECBC specifications
Proposed building model with your design
Annual energy consumption comparison
Documentation for authority approval
Support during plan scrutiny

For ECBC+ and SuperECBC: Demonstrate 25% and 50% better performance than standard ECBC through advanced simulation

ECBC Compliance Benefits:

Legal requirement for specified buildings
Reduced energy costs (30-50% vs. non-compliant)
Faster approvals in many jurisdictions
Eligibility for incentives and FAR bonuses
Green building certification prerequisites

Deliverables:

ECBC-compliant baseline model
Proposed building model
Compliance calculation sheets
Detailed comparison report
Certification documentation
Support for statutory submissions

Investment: ₹75,000-2,50,000 depending on building size and complexity

3. Daylighting Analysis & Simulation

Natural daylight reduces lighting energy, improves occupant well-being, and is essential for green building certifications.

What We Analyze:

Daylight Metrics:

Daylight Factor (DF): Percentage of outdoor light reaching indoor spaces
Spatial Daylight Autonomy (sDA): Percentage of space receiving sufficient daylight
Annual Sunlight Exposure (ASE): Measure of excessive direct sunlight causing glare
Useful Daylight Illuminance (UDI): Illuminance in the “useful” range (100-2000 lux)
Daylight Glare Probability (DGP): Risk of glare discomfort

What We Study:

Window sizes and placement optimization
Glass specifications (VLT, tint)
Shading devices (louvers, overhangs, fins)
Skylights and roof monitors
Light shelves and reflective surfaces
Interior surface reflectances
Furniture and partition layouts
Seasonal and hourly variations

Software We Use:

Radiance: Research-grade ray-tracing engine, most accurate
DIVA for Rhino: Climate-based daylighting metrics
ClimateStudio: Fast, accurate daylighting and glare analysis
Dialux: Lighting design with daylighting integration
AGi32: Comprehensive lighting and daylighting tool
IES VE: Integrated daylighting with energy simulation

Benefits:

Reduce artificial lighting energy by 30-60%
Improve occupant productivity and satisfaction
Meet green building certification requirements (LEED, IGBC, GRIHA)
Demonstrate compliance with NBC daylight requirements
Optimize facade design for views and daylight balance
Minimize glare problems before construction

Deliverables:

Daylight factor calculations
Climate-based daylight metrics (sDA, ASE, UDI)
False color renderings showing light levels
Annual daylight availability charts
Glare analysis reports
Design recommendations for improvements
Compliance documentation for certifications

Applications:

Office buildings (especially critical for occupant comfort)
Educational facilities (classrooms, libraries)
Healthcare facilities (patient rooms, corridors)
Retail spaces (enhancing merchandise presentation)
Museums and galleries (controlled daylighting)
Residential buildings (living spaces, bedrooms)

Timeline: 1-3 weeks Investment: ₹40,000-1,50,000

4. Computational Fluid Dynamics (CFD) Simulation

CFD provides detailed 3D visualization of air movement, temperature distribution, and thermal comfort—far more detailed than standard energy models.

What CFD Reveals:

Airflow Patterns:

Air velocity distribution throughout spaces
Dead zones with stagnant air
Short-circuiting in ventilation systems
Stratification and air mixing
Natural ventilation effectiveness

Temperature Distribution:

Hot and cold spots identification
Thermal stratification
Mean radiant temperature (MRT)
Surface temperatures of walls, floors, ceilings

Thermal Comfort:

PMV (Predicted Mean Vote): Thermal sensation scale
PPD (Predicted Percentage Dissatisfied): Occupant dissatisfaction
Draft risk assessment
Vertical temperature gradients
Asymmetric radiant temperature

Indoor Air Quality:

Contaminant dispersion
CO2 concentration mapping
Ventilation effectiveness
Pathogen transmission risk (post-COVID consideration)

Applications:

HVAC System Design:

Optimal diffuser placement and selection
Supply air temperature and flow rate optimization
Return air grille locations
Under-floor vs. overhead distribution
Displacement ventilation design

Natural Ventilation:

Cross-ventilation effectiveness
Stack effect utilization
Window and vent sizing
Courtyard and atrium ventilation
Wind-driven ventilation

Large Spaces:

Atriums and lobbies
Auditoriums and theaters
Airports and terminals
Manufacturing facilities
Data centers (critical for hot spot prevention)

Specialized Applications:

Clean rooms and laboratories
Hospital operating rooms
Industrial facilities with process heat
Kitchen and restaurant ventilation
Indoor swimming pools

Software We Use:

Autodesk CFD: User-friendly with good accuracy
ANSYS Fluent: Industry-standard for complex flows
OpenFOAM: Open-source, highly customizable
IES MicroFlo: Integrated with energy simulation
PHOENICS: Specialized for building applications

Deliverables:

3D velocity vector plots
Temperature contour maps
Comfort parameter maps (PMV, PPD)
Air age and ventilation effectiveness
Quantitative performance metrics
Design recommendations
Animated visualizations
Comprehensive technical report

Timeline: 2-4 weeks depending on complexity Investment: ₹1,00,000-5,00,000

5. Solar Analysis & PV System Modeling

Understand solar radiation on your building and optimize photovoltaic system design.

Solar Radiation Analysis:

Annual solar radiation on facades and roofs
Hourly/monthly solar heat gain
Shading analysis from surrounding buildings and trees
Optimal panel orientation and tilt
Seasonal variations

PV System Performance Modeling:

Annual energy generation predictions
System efficiency accounting for:

Temperature effects
Inverter losses
DC to AC conversion
Soiling and degradation

Hourly generation profiles
Grid export vs. self-consumption analysis
Battery storage optimization
Financial analysis (payback, IRR, NPV)

Software We Use:

PVsyst: Industry-standard PV system design
Helioscope: Fast, accurate PV modeling
SAM (System Advisor Model): NREL’s comprehensive renewable energy tool
SketchUp with solar plugins: 3D solar analysis
ClimateStudio: Solar radiation with energy simulation

Deliverables:

Site solar resource assessment
Optimal PV array layout
Annual energy production forecast
Financial analysis with incentives
Shading loss analysis
String configuration recommendations
Equipment specifications
Comprehensive feasibility report

Investment: ₹30,000-1,50,000

6. Thermal Comfort Analysis

Ensure occupant comfort through detailed analysis of thermal conditions.

What We Analyze:

Thermal Comfort Parameters:

Air temperature
Mean radiant temperature (MRT)
Air velocity
Relative humidity
Metabolic rate (activity level)
Clothing insulation

Comfort Indices:

PMV/PPD: Fanger’s Predicted Mean Vote and Percentage Dissatisfied
Operative Temperature: Combined effect of air and radiant temperature
SET (Standard Effective Temperature)
Adaptive Comfort: For naturally ventilated buildings per ASHRAE 55

Analysis Methods:

Zonal Analysis: Using energy simulation software to predict average comfort conditions in each thermal zone

Detailed Spatial Analysis: Using CFD to map comfort conditions at every point in a space, revealing local discomfort

Applications:

Optimize HVAC system design
Design radiant heating/cooling systems
Plan furniture layouts for comfort
Design naturally ventilated spaces
Investigate comfort complaints in existing buildings
Demonstrate compliance with standards (ASHRAE 55, ISO 7730)

Deliverables:

Comfort parameter calculations
PMV/PPD maps showing spatial variations
Compliance assessment with comfort standards
Identification of thermal discomfort zones
Design recommendations for improvements

Timeline: 1-2 weeks (zonal), 2-3 weeks (CFD spatial) Investment: ₹40,000-1,50,000

7. Parametric Analysis & Design Optimization

Compare multiple design options systematically to find the optimal solution.

What We Optimize:

Building Envelope:

Wall insulation thickness and materials
Roof insulation and reflectivity (cool roofs)
Window-to-wall ratio (WWR)
Glass specifications (U-value, SHGC, VLT)
Shading devices (depth, angle)
Building orientation

HVAC Systems:

System type comparison (VRF vs. chilled water vs. DX)
Chiller efficiency (COP)
Setpoint temperatures
Ventilation rates
Economizer strategies
Equipment sizing

Lighting:

Lighting power density (LPD)
Control strategies (occupancy, daylight)
LED color temperature and CRI

Renewable Energy:

Solar PV system sizing
Solar water heating
Battery storage capacity

Optimization Process:

Step 1: Baseline Create model of current design or standard practice

Step 2: Parametric Runs Systematically vary each design parameter

Step 3: Analysis Compare energy, cost, and comfort metrics

Step 4: Optimization Identify optimal combination of measures

Step 5: Sensitivity Analysis Test robustness of recommendations

Deliverables:

Baseline performance metrics
Parametric study results matrix
Energy and cost savings for each option
Pareto frontier showing optimal solutions
Sensitivity analysis
Prioritized recommendations with ROI
Final optimized design specifications

Benefits:

Objective comparison of design alternatives
Identify best-performing strategies
Balance initial cost vs. operating savings
Support value engineering decisions
Maximize green building certification points

Investment: ₹75,000-3,00,000 depending on number of parameters

8. Retrofit & Renovation Modeling

For existing buildings, simulation identifies the most cost-effective upgrades.

Our Process:

Step 1: Baseline Calibration Create a model of existing building and calibrate it with actual utility bills to ensure accuracy

Step 2: Energy Conservation Measure (ECM) Analysis Model individual retrofit measures:

Lighting upgrades (LED retrofits)
HVAC improvements (chiller replacement, VFDs, controls)
Building envelope upgrades (insulation, window replacement)
Renewable energy additions
Building automation systems

Step 3: Package Analysis Combine measures into cost-effective packages

Step 4: Financial Analysis Calculate savings, costs, payback, NPV, IRR for each package

Typical ECMs We Model:

LED lighting retrofits
HVAC system replacement or upgrades
Building Management System (BMS) installation
Variable Frequency Drives (VFDs) on motors
Cool roof coatings
Window films or replacement
Insulation improvements
Solar PV installation
Water-cooled chiller upgrades
Economizer additions

Deliverables:

Calibrated baseline model
Individual ECM performance and economics
ECM packages with cumulative savings
Implementation priority recommendations
Measurement and verification (M&V) plan
ESCO/financing-ready reports

Applications:

Major building renovations
Energy service company (ESCO) projects
Investment-grade audits
Green building certification for existing buildings

Timeline: 3-6 weeks including calibration Investment: ₹1,00,000-4,00,000

9. Climate-Responsive Design Studies

Optimize building design for India’s diverse climate zones.

India’s Climate Zones (NBC):

Hot & Dry: Rajasthan, parts of Gujarat, Maharashtra
Warm & Humid: Coastal regions, Kerala, Goa
Composite: Delhi, Jaipur, Ahmedabad (extreme seasons)
Temperate: Bangalore, Pune
Cold: Himalayan regions

Climate-Specific Strategies We Analyze:

Hot & Dry Climates:

Thermal mass for temperature damping
Courtyards and shaded outdoor spaces
Evaporative cooling feasibility
Night ventilation strategies
High roof insulation

Warm & Humid Climates:

Maximum natural ventilation
Shading from direct sun
Reduced thermal mass (faster cooling)
Dehumidification strategies
Elevated buildings for air circulation

Composite Climates:

Seasonal strategies (winter heating, summer cooling)
Adaptive building envelope
Mixed-mode ventilation
Thermal storage for shoulder seasons

What We Deliver:

Climate analysis for your specific location
Passive design strategy recommendations
Optimized building orientation
Shading device design
Natural ventilation feasibility
Seasonal operation strategies
Energy and comfort predictions

Investment: ₹50,000-2,00,000

10. Life Cycle Assessment (LCA) Simulation

Analyze environmental impact beyond just operational energy.

What We Assess:

Embodied Carbon: Carbon emissions from material extraction, manufacturing, transportation, and construction

Operational Carbon: Carbon emissions from energy use during building operation

End-of-Life: Emissions from demolition, waste, and recycling

Life Cycle Stages:

A1-A3: Product stage (extraction, transport, manufacturing)
A4-A5: Construction stage (transport, installation)
B1-B7: Use stage (operation, maintenance, replacement)
C1-C4: End-of-life (demolition, waste processing)

Environmental Indicators:

Global Warming Potential (GWP): kg CO2 equivalent
Embodied Energy: MJ per kg or per m²
Water consumption
Resource depletion
Eutrophication, acidification

Software & Standards:

One Click LCA: Comprehensive LCA tool
Tally (Revit plugin): BIM-integrated LCA
GaBi/SimaPro: Detailed LCA software
ISO 14040/14044: LCA methodology standards
EN 15978: Assessment of environmental performance of buildings

Applications:

Material selection (low-carbon alternatives)
Net Zero carbon building design
Green building certifications (LEED MR, IGBC Materials)
Corporate sustainability reporting
Comparison of construction systems

Deliverables:

Whole building LCA results
Material-by-material breakdown
Comparison of design alternatives
Recommendations for carbon reduction
Certification documentation

Investment: ₹1,00,000-4,00,000 depending on detail

Our Simulation Methodology

Step 1: Project Briefing & Data Collection

Understand project goals and constraints
Collect architectural drawings (floor plans, sections, elevations)
Gather MEP system information
Obtain local weather data
Define analysis scope and deliverables

Step 2: Model Development

Create 3D building geometry
Define thermal zones
Input envelope properties (walls, roofs, windows)
Model HVAC systems and controls
Input lighting and equipment loads
Define occupancy schedules
Apply local weather data

Step 3: Model Validation & Calibration

Check inputs for consistency
Run diagnostic checks
For existing buildings: calibrate with utility bills
Peer review of model setup

Step 4: Baseline Simulation

Run annual simulation (8,760 hours)
Generate baseline energy consumption
Calculate performance metrics (EUI, energy costs)
Identify major energy end-uses

Step 5: Parametric Analysis (if applicable)

Systematically vary design parameters
Run simulations for each scenario
Compare results quantitatively

Step 6: Results Analysis

Analyze hourly/monthly energy profiles
Calculate energy savings
Perform financial analysis (simple payback, NPV, IRR)
Benchmark against standards and best practices
Identify optimization opportunities

Step 7: Reporting & Presentation

Comprehensive technical report
Executive summary for management
Visual presentations (charts, graphs, 3D renderings)
Recommendations prioritized by impact and cost
Presentation to design team

Step 8: Implementation Support (optional)

Design documentation support
Specifications for equipment and materials
Contractor coordination
Construction phase monitoring
Commissioning support

Software & Tools We Master

Energy Simulation Engines

EnergyPlus

DOE’s flagship engine, most detailed and accurate
Hourly energy simulation with comprehensive physics
Used for LEED, IGBC, ECBC compliance
Open-source, constantly improved

eQUEST (DOE-2 engine)

Fast, intuitive, widely accepted
Excellent for code compliance
Hourly and parametric simulations
User-friendly graphical interface

TRACE 700/3D Plus

Trane’s comprehensive HVAC design tool
Equipment sizing integrated with energy analysis
Good for load calculations and system selection

Integrated Environments

DesignBuilder

EnergyPlus with intuitive 3D modeling
Integrated CFD and daylighting
Excellent visualization
Fast learning curve

IES VE (Virtual Environment)

Comprehensive suite covering energy, daylight, CFD, solar
BIM integration (Revit, ArchiCAD)
Advanced features for complex buildings
Used by leading consultants globally

OpenStudio

Open-source graphical interface for EnergyPlus
Parametric analysis tool (PAT)
Measures library for common strategies
SketchUp plugin

Daylighting Simulation

Radiance

Research-grade ray-tracing, most accurate
Climate-based daylight metrics
Complex geometries and materials
Open-source

DIVA for Rhino

Radiance integration with Rhino
Climate-based metrics (sDA, ASE, UDI)
Glare analysis (DGP)
Grasshopper parametric integration

ClimateStudio

Fastest and most accurate daylighting tool
Rhino plugin
Energy, daylight, glare, thermal comfort
Intuitive workflows

Dialux/Dialux EVO

Professional lighting design
Daylighting integration
IES photometric files
Free software

CFD Simulation

Autodesk CFD

User-friendly interface
Thermal comfort and ventilation analysis
Reasonable accuracy for buildings
Integration with Revit

ANSYS Fluent

Industry-standard CFD
Most powerful for complex flows
Accurate but steep learning curve
Used for critical applications (data centers, hospitals)

OpenFOAM

Open-source CFD
Highly customizable
Cost-effective for complex problems
Active user community

IES MicroFlo

Building-specific CFD
Integration with IES VE
Natural and mechanical ventilation
Good for typical building applications

Solar & Renewable Energy

PVsyst

Industry-standard for PV system design
Detailed shading analysis
Financial modeling
Internationally recognized

SAM (System Advisor Model)

NREL’s renewable energy tool
Solar PV, CSP, wind, biomass
Detailed financial modeling
Free from NREL

Helioscope

Cloud-based PV design
Fast and accurate
3D shading analysis
Used by solar installers

Specialized Tools

Sefaira (SketchUp/Revit plugin)

Real-time energy feedback during design
Parametric studies
Daylight and glare
Cloud-based

Ladybug Tools (Grasshopper)

Climate analysis
Solar radiation
Daylight
Outdoor comfort
Open-source and parametric

WINDOW/THERM (LBNL)

Detailed window and thermal bridge analysis
Material properties
U-factor and SHGC calculations
Free from LBNL

Industries & Building Types We Serve

Commercial Buildings

Office buildings and corporate parks
Retail centers and malls
Hotels and hospitality
Restaurants and food services
Banks and financial institutions
Data centers

Institutional Buildings

Educational facilities (schools, colleges, universities)
Government offices
Hospitals and healthcare facilities
Libraries and museums
Research laboratories
Community centers

Industrial Facilities

Manufacturing plants
Warehouses and distribution centers
Food processing units
Pharmaceutical facilities
Clean rooms
Cold storage

Residential Buildings

Individual homes and villas
Apartment buildings
Residential townships
Senior living facilities
Student housing

Specialized Facilities

Airports and terminals
Metro stations and railway facilities
Convention centers
Sports complexes
Indoor swimming pools
Auditoriums and theaters

Why Choose Ensimulated Solutions for Building Simulation?

1. Expert Team with Deep Experience

Mr. Saibal Saha leads our simulation team with:

30+ years of experience in energy efficiency and building design
BEE Certified Energy Auditor
ECBC Master Trainer and Expert Professional
IGBC Accredited Professional & Fellow
GRIHA Certified Professional
Certified Professional in Life Cycle Assessment

Our team has completed 100+ simulation projects across diverse building types and climate zones throughout India.

2. Multi-Software Proficiency

We’re not limited to one tool. We select the best software for each project:

EnergyPlus/eQUEST/DesignBuilder for detailed energy analysis
Radiance/DIVA/ClimateStudio for daylighting
CFD tools for thermal comfort and air quality
PVsyst/SAM for renewable energy
LCA software for embodied carbon

3. Practical, Implementable Recommendations

We don’t just deliver reports that sit on shelves. Our recommendations are:

Cost-effective: Focus on measures with good ROI
Practical: Suitable for Indian construction practices and availability
Prioritized: Clear ranking by impact and feasibility
Detailed: Specifications ready for procurement

4. Comprehensive Service

From initial concept through construction and operation:

Early-stage: Climate analysis and passive design strategies
Design phase: Detailed energy modeling and optimization
Documentation: ECBC and certification compliance reports
Construction: Monitoring and change order evaluation
Operations: Commissioning support and troubleshooting

5. Green Building Integration

Simulation is integral to green building certification:

IGBC: Energy performance credits
LEED: EAc1 Optimize Energy Performance (up to 21 points)
GRIHA: Energy simulation and benchmarking
ECBC: Mandatory compliance demonstration

We handle all simulation requirements for certifications seamlessly.

6. Regulatory Expertise

We stay current with:

Latest ECBC code versions and amendments
State-specific building regulations
NBC energy requirements
BEE guidelines
Emerging policies

7. Fast Turnaround

We respect project schedules:

Standard energy model: 2-3 weeks
Daylighting study: 1-2 weeks
CFD analysis: 2-3 weeks
Comprehensive package: 4-6 weeks

Rush services available for time-critical projects.

8. Competitive Pricing

Our rates are fair and transparent:

No hidden costs
Fixed-price or time-and-materials options
Volume discounts for multiple buildings
Long-term partnerships valued

9. Client-Focused Approach

Clear communication throughout
Regular progress updates
Flexible to accommodate design changes
Training provided on interpreting results
Post-delivery support for questions

10. Trusted by Leading Organizations

Our clients include:

Reserve Bank of India
Southeastern Railway
Axis Bank Limited
Ambuja Neotia Group
Peerless Group
Leading architects and MEP consultants