Jelly is a design brand based in Berlin. The idea for Jelly emerged from an experimental building project by Julian Meisen and Hans von Bülow, founders of the architecture studio Common Agency, together with Saqib Aziz, whose work moves between engineering, computation, and fabrication.
Their collaboration sparked the ambition to bring the structural and material-efficient principles of digital component optimization into progressive furniture design – connecting algorithmic geometry, sustainable production, and sensual form.
Jelly's objects are made from biobased PLA: a thermoplastic polymer based on renewable resources like corn starch. The bioplastic is biodegradable and also suited for circular reprocessing enabling future life cycles in new forms. The material's translucency reveals the internal structure of each object and turns construction into part of the design.
The sustainable approach continues in the sourcing of the material itself. Jelly works with local PLA suppliers in Germany, keeping transport routes short and material quality reliable.
The additive manufacturing process is precise, direct, and material-efficient. Rather than hiding fabrication, it leaves a visible trace in each object: fine printed lines, a soft surface rhythm, and a structure that can be read from the outside. This makes FDM 3D printing part of the visual language, not just the production method.
Jelly's objects are made in Berlin, which keeps design, prototyping, and production connected in one place. This allows for direct control over quality, consistency, and detail.
Emerging from the intersection of design and computation, Jelly combines playful deformation with structural intelligence. Each object reimagines familiar furniture types through a process of controlled variation. Bodily shapes, biological patterns, and structural logic come together in forms that feel both intuitive and unexpected.
A custom-built algorithm allows every object to morph through an open range of iterations while continuously adjusting its structural system for optimized performance and material efficiency.
Jelly is a design brand based in Berlin. The idea for Jelly emerged from an experimental building project by Julian Meisen and Hans von Bülow, founders of the architecture studio Common Agency, together with Saqib Aziz, whose work moves between engineering, computation, and fabrication.
Their collaboration sparked the ambition to bring the structural and material-efficient principles of digital component optimization into progressive furniture design – connecting algorithmic geometry, sustainable production, and sensual form.
Jelly's objects are made from biobased PLA: a thermoplastic polymer based on renewable resources like corn starch. The bioplastic is biodegradable and also suited for circular reprocessing enabling future life cycles in new forms. The material's translucency reveals the internal structure of each object and turns construction into part of the design.
The sustainable approach continues in the sourcing of the material itself. Jelly works with local PLA suppliers in Germany, keeping transport routes short and material quality reliable.
The additive manufacturing process is precise, direct, and material-efficient. Rather than hiding fabrication, it leaves a visible trace in each object: fine printed lines, a soft surface rhythm, and a structure that can be read from the outside. This makes FDM 3D printing part of the visual language, not just the production method.
Jelly's objects are made in Berlin, which keeps design, prototyping, and production connected in one place. This allows for direct control over quality, consistency, and detail.
Emerging from the intersection of design and computation, Jelly combines playful deformation with structural intelligence. Each object reimagines familiar furniture types through a process of controlled variation. Bodily shapes, biological patterns, and structural logic come together in forms that feel both intuitive and unexpected.
A custom-built algorithm allows every object to morph through an open range of iterations while continuously adjusting its structural system for optimized performance and material efficiency.
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