I am a detail-oriented 3D Product Designer specializing in high-complexity geometry and parametric surfaces. My journey began in medical science, where I learned the value of precision at a microscopic level, which I now apply to creating luxurious and intricate designs that meet rigorous production standards.

Shiva Zamaninejad

I am a detail-oriented 3D Product Designer specializing in high-complexity geometry and parametric surfaces. My journey began in medical science, where I learned the value of precision at a microscopic level, which I now apply to creating luxurious and intricate designs that meet rigorous production standards.

Available to hire

I am a detail-oriented 3D Product Designer specializing in high-complexity geometry and parametric surfaces. My journey began in medical science, where I learned the value of precision at a microscopic level, which I now apply to creating luxurious and intricate designs that meet rigorous production standards.

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Work Experience

Independent 3D Design & R&D Specialist at Self-Employed
January 1, 2021 - Present
Currently establishing a specialized design practice in Denmark focusing on luxury decorative objects. Conducting technical research into 'Zero-Breakage' geometries for high-end artistic molds.
Consultant & Design Researcher at Freelance
January 1, 2021 - January 1, 2023
Delivered precision-based 3D assets for international creative projects, focusing on the intersection of aesthetic art and industrial feasibility.

Education

Doctorate in Medical Science at Not specified
January 11, 2030 - April 9, 2026
Advanced Study in Computational Design at Self-Directed Mastery
January 11, 2030 - April 9, 2026

Qualifications

Add your qualifications or awards here.

Industry Experience

Manufacturing, Media & Entertainment
    uniE621 Organic Topographic Sculptures: Fluid Form Exploration
    A study in fluid dynamics and topographic layering. These pieces represent a bridge between natural erosion patterns and digital craftsmanship. • NURBS Modeling Excellence: Focuses on seamless curvature and G2 continuity to create "liquid-like" transitions between different materials (Marble, Wood, and Glass). • Multi-Material Integration: Designed as a modular system where organic voids are filled with contrasting textures, showcasing an understanding of material tolerances and assembly.
    uniE621 Parametric Mandala Tray: High-Precision Decorative Geometry
    This project explores the intersection of traditional spiritual patterns and modern algorithmic design. • Algorithmic Pattern Generation: The intricate mandala surface was developed using parametric tools to ensure perfect symmetry and varying depths for a 3D tactile experience. • Material & Light Interaction: Designed with material refraction in mind, the faceted surfaces are optimized to capture and reflect light from multiple angles, enhancing the visual depth of the product. • Luxury Product Design: Targeted for the high-end home decor market, focusing on "un-manufacturable" complexities that can only be achieved through advanced 3D modeling.
    uniE621 Modular Industrial Drainage System: Advanced Fluid Management Design
    This project demonstrates the design and modeling of a heavy-duty industrial drainage infrastructure, focused on efficient fluid dynamics and modular installation. Key Engineering & Design Highlights: • High-Capacity Flow Architecture: The internal geometry is optimized to handle high-volume fluid discharge while preventing sediment buildup through a self-scouring channel profile. • Modular Interlocking System: Engineered with a precision interlocking mechanism that allows for rapid onsite assembly and ensures a leak-proof connection between segments. • Structural Load Distribution: The external ribbing and reinforcement patterns are designed to withstand significant vertical pressure, making it suitable for high-traffic industrial environments. • Maintenance-Friendly Access: Features an integrated removable grating system designed for easy inspection and debris removal without compromising structural integrity. • Material-Efficient Design: Developed using parametric optimization to reduce material usage while maintaining maximum mechanical strength. Software: Rhinoceros (Mechanical Modeling), High-Fidelity Technical Visualization.
    uniE621 Geometric Confectionery Mold: Industrial Production Design
    This project focuses on the technical engineering of a high-precision confectionery mold designed for rigid-body mass production. The primary objective was to transform a complex parametric pattern into a manufacturable industrial tool. Technical Specifications: • Draft Angle Engineering: All vertical facets are engineered with a 1.5° to 2° draft angle. This ensures clean, frictionless de-molding of the final product, preserving the integrity of the sharp geometric edges. • Rigid Polycarbonate Specification: Designed as a non-flexible, high-grade Polycarbonate (PC) mold. This rigid structure provides superior dimensional stability and zero deformation compared to silicone alternatives. • NURBS-Based Surface Continuity: Modeled using high-fidelity NURBS geometry to achieve a mirror-finish surface. This ensures that the cast chocolate inherits a high-gloss texture directly from the mold. • Mass-Production Layout: The multi-cavity assembly is optimized for consistent thermal distribution during the cooling phase, facilitating efficient industrial workflows. Software: Rhinoceros (NURBS Modeling), KeyShot/AI Visualization.
    uniE621 Parametric Hydro-Culture Planter: Advanced Capillary Irrigation System
    This project represents a sophisticated fusion of parametric design and functional botanical engineering. The goal was to create a high-end indoor planter that manages plant health through precise digital geometry. Key Design & Technical Features: • Integrated Capillary Irrigation: The core functionality is based on an internal capillary system that regulates water delivery directly to the root zone. This ensures consistent moisture levels, preventing both dehydration and root rot. • Dedicated Irrigation Port: A strategically placed irrigation vent allows for easy reservoir refilling and water level monitoring without disturbing the plant or the outer decorative shell. • Advanced Geometric Architecture: The outer form is a result of precise geometric transformations, featuring a twisted hexagonal structure. This design provides both high-end aesthetic appeal and exceptional structural stability. • Debris-Control Aeration System: A critical engineering detail is the integration of downward-angled aeration vents in the internal liner. These vents facilitate optimal oxygen flow to the roots while acting as a physical barrier that prevents soil particles from escaping into the outer chamber or water reservoir. • Maintenance-Free Design: The dual-shell modular assembly is engineered for a perfect fit, ensuring a clean and sustainable environment for delicate indoor plants. Software Used: Rhinoceros (Advanced NURBS Modeling), V-Ray/AI for High-Fidelity Visualization.

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