Industrial Solar Power Infrastructure

Engineering-first EPC for 50kW-1MW commercial & industrial installations

MW Engineered

±1.5°

Mounting Tolerance

25+

Year Design Life

142

Point Site Assessment

Request Technical Site Audit View Engineering Process

ENGINEERING-FIRST METHODOLOGY

Solar as Critical Power Infrastructure

When production lines depend on consistent power, solar arrays become engineering assets—not just installations.

Single-Point Engineering Accountability

One team responsible from structural analysis to final commissioning protocol.

Unified technical responsibility
End-to-end quality control
Structural warranty management

Precision Fabrication & Installation

Factory-calibrated assembly with ±1.5° mounting tolerance.

ISO-certified fabrication
Laser-aligned mounting
Corrosion-resistant materials

25+ Year Operational Reliability

Designed for industrial environments with chemical, thermal, and load challenges.

Climate-specific degradation modeling
Maintenance accessibility design
Corrosion protection systems

Structural Engineering Standards

IS 800:2007 - General Construction Steel
IS 875:2015 - Wind Load Standards
Factory Mutual Global - Industrial Standards
Site-Specific Seismic & Corrosion Analysis

142

Engineering Checkpoints

The Engineering Workflow

A systematic 4-phase approach ensuring every project meets industrial power reliability standards.

Site Forensics

142-Point Technical Assessment

Load Dynamics

Precision Engineering Design

Precision Fabrication

Factory-Calibrated Assembly

Commissioning Protocol

System Validation & Handover

Site Forensics

142-Point Technical Assessment

Phase 1

Engineering Activities

Structural load capacity analysis
Geotechnical investigation
Environmental exposure profiling
Grid interconnection feasibility

Technical Deliverables

Site Assessment Report
Structural Feasibility Study

Engineering Documents

Sample engineering drawings, calculation sheets, and QC reports for this phase

View Sample

ENGINEERING COMPARISON

Why Engineering Depth Matters

Technical Parameter	Our Engineering Approach	Typical EPC Approach	Impact on Reliability
Wind Load Calculation	IS 875 Part 3 + Site-Specific Anemometer Data	Generic Zone-Based Estimates	Prevents 85% of wind-related failures in coastal zones
Foundation Design	Geotechnical Report + Dynamic Load Analysis	Standard Template Application	Eliminates settlement issues in unstable soil conditions
DC/AC Ratio	Climate-Adjusted Annual Simulation	Rule of Thumb Application	Optimizes inverter efficiency by 12-18% annually
Maintenance Access	3D Modeling of Service Pathways	Post-Installation Consideration	Reduces maintenance time by 40% over asset lifetime

Engineering Depth Translates to Operational Stability

Each additional engineering checkpoint reduces long-term operational risk by an estimated 15-20%. Our comprehensive approach prevents common failure points that typical installations encounter after 5-7 years.

Our Technology & Implementation Partners

We work with globally proven manufacturers and agri-technology leaders to ensure reliability, longevity, and field performance.