Material Science, Engineered for Textiles
Deep expertise across core areas of technical textile innovation, each supported by proprietary methods and a growing patent portfolio.
Three Pillars of R&D
Basic Research
Generating fundamental knowledge and understanding without immediate commercial goals. Foundational work explores new scientific principles.
Applied Research
Using existing knowledge to solve specific problems or develop new applications. Bridges the gap between theory and practical implementation.
Development
Turning research insights into tangible products, services, or processes through prototyping, testing, and refinement for market readiness
Research Domains
Focused expertise across key technical textile research domains, supported by material science–driven development, in-house validation, and proprietary innovation pathways.
Polymer Engineering
Advanced polymer formulation and processing for high-performance textiles. We engineer custom polymer blends for exceptional durability, chemical resistance, and functional properties tailored to extreme environments.
Focus Area
High Performance Polymers
Molecular Characterization
Custom Formulation
Fiber Spinning
Strategic Importance: Foundational capability enabling wide area research domains.
Functional Fibers
Development of specialty fibers with integrated functionality. From carbon-enhanced performance fibers to thermally-responsive yarns, our functional fiber platform creates new material possibilities for demanding applications.
Focus Area
High Strength Synthetics
Carbon Fiber Integration
Bio-based Fibers
Thermal Fibers
Strategic Importance: Growing demand from automotive and construction sectors brings potential.
Advanced Coatings
Proprietary coating systems that enhance textile functionality without compromising breathability or durability. Our coating technologies provide UV protection, water repellency, antimicrobial properties, and enhanced performance for outdoor and industrial textiles.
Focus Area
Nano Coatings
Antimicrobial Treatments
Water Repellency
UV Protection
Strategic Importance: Critical bridge between materials science and end-use performance, allowing rapid customization for diverse applications.
Smart Textiles
Research & Development of intelligent fabrics with embedded sensing and responsive capabilities. Our research in area’s of smart textiles platform integrates nanotechnology and advanced polymers to create temperature-regulating, and electrically conductive textiles for industrial applications.
Focus Area
Conductive Fabrics
Temperature Regulation
Embedded sensors
Self-Healing Textiles
Strategic Importance: Foundational capability for next-generation textiles, where sensing, response, and connectivity are embedded at material level.
Research Capabilities & Infrastructure
Advanced Laboratory
- Fiber spinning and characterization equipment
- Coating application systems
- Polymer processing simulation facilities
- Real-time quality monitoring
Testing & Validation
- Physical property analysis
- Mechanical property analysis
- Chemical resistance evaluation
- Durability assessment protocols
Research Team
- PhD-level materials scientists
- Industry innovation experts
- Experienced Textile Engineers
- Quality assurance specialists
Key Research Projects
Proprietary Blends – IFR Yarns and Fabrics
Engineered IFR Yarns & Fabrics for Multi-Hazard Workwear
Development of next-generation IFR textile platforms engineered for HRC level arc and flame protection. Our research is actively focusing on proprietary fiber blending and fabric engineering to achieve high thermal stability, low heat transfer, and structural integrity under extreme exposure conditions.
Smart Wearables – Conductive Fibers
Conductive Fiber Systems for Medical-Grade Smart Wearables
We are advancing conductive fiber and fabric architectures that embed electrical conductivity and sensor functionality within textiles for medical-grade wearables. Current research targets reliable heart rate sensing and localized temperature regulation while maintaining flexibility, durability, and skin compatibility.
Sustainable Denims – Hemp Blends
Material-Engineered Hemp Denims
Developing hemp-blended denim fabrics through material engineering and controlled fiber blending to improve durability, comfort, and environmental performance. Our laboratory work actively integrates low-impact processing, resource efficiency, and circular design principles, advancing next-generation sustainable solutions.
Recycled Polyester – Upholstery
High-Performance – Durable Home Textiles Solutions
We are developing upholstery-grade fabrics using recycled polyester to enhance durability, aesthetics, and lifecycle performance. Our laboratory work actively integrates material optimization, low-impact processing, and circular design strategies, enabling scalable and responsible home textile solutions.
Glass Resinated Composite – Agricultural Structures
Composite Systems for High-Stability Agricultural Structures
We are developing glass fiber–resinated composite textile systems for agricultural structural applications, with a strong focus on mechanical stability and durability. Our laboratory work actively engineers fiber–resin interfaces and structural architectures to deliver reliable performance.
Proprietary Blends – Compostable Granules
Engineered Compostable Granules Sustainable Packaging
We are engineering proprietary compostable granule systems that integrate sustainability and circularity into packaging textile materials. The research focuses on material stability during use and predictable biodegradation after disposal, enabling responsible next-generation packaging applications.
Engineered Fabrics for Thermal Insulation
Precision-Engineered Insulating Fabrics for Home Textiles
We are engineering thermal insulation fabrics for infant home textiles using material-science-driven design. The research emphasizes uniform heat distribution, lightweight construction, and engineering materials that balance heat retention, airflow, and long-term fabric stability with comfort.
Hydrophobic and Oleophilic – Fabric Development
Engineered Hydrophobic–Oleophilic Fabrics for Filtration
We are developing hydrophobic and oleophilic fabric systems engineered for selective fluid separation in filtration applications. Our laboratory work actively optimizes fiber surfaces, fabric structures, and coating-free or low-additive treatments to enhance oil affinity while repelling water.
Flame Retardant – Advanced Cotton Fabrics
Advanced FR Cotton Systems for Pro-Tech Textiles
We are developing advanced flame-retardant cotton fabrics for Pro-Tech applications through material engineering and controlled fabric construction. Our laboratory work focuses on achieving reliable flame resistance, thermal stability, and fabric durability while preserving the comfort and breathability of cotton.
Sportswear Development – Cooling Tech
Engineered Cooling Fabrics for High-Performance Sportswear
We are developing high-performance cooling fabric systems for sportswear that actively reduce skin temperature during intense physical activity. Our laboratory work focuses on fabric architecture, moisture transport, and thermal dissipation mechanisms to enhance comfort and sustained athletic performance.
Examination Gloves – New Hybrid Blends
Hybrid Nitrile–Latex Material Systems for Next-Gen Gloves
We are developing next-generation examination glove materials using engineered blends of nitrile and latex to balance elasticity, tactile sensitivity, and barrier performance. Our laboratory work actively focuses on blend compatibility, mechanical integrity, and process stability, enabling a new age class.
Wool Denim – New Blends Development
Next-Gen Denim Using Engineered Wool Blends
We are developing wool-blend denim fabrics through controlled fiber blending and fabric engineering to introduce enhanced thermal comfort, breathability, and drape into denim structures. Our laboratory work actively focuses on yarn architecture, weave optimization, enabling a new category of engineered fashion applications.