In this project, a triangulated mesh system is developed as a tension-based form-finding structure that transforms under gravity into a compression-only geometry. Laser-cut triangular modules are connected into a continuous network, where differences in module scale produce a gradient between smooth, organic curvature and more faceted, directional surfaces. The mesh is suspended from a field of vertical supports that can be repositioned and adjusted in height, allowing the structure to adapt to changing boundary conditions. Through this system, form is not predetermined but emerges from the interaction between geometry, material, and force. Areas of higher triangular resolution register subtle curvature and more continuous surfaces, while larger modules produce sharper, more articulated geometries, creating a spatial gradient across the structure. The resulting configurations suggest lightweight shells or canopy structures that could be inverted into compression forms, demonstrating how a simple modular system can generate complex architectural space through physical form-finding.