https://protoctrl.com/portfolio/hypergraphs-2026/ 2026-03-25T08:57:33+01:00 https://protoctrl.com/wp-content/uploads/2026/03/26-03_RS_Hypergraphs_01.jpg Hypergraphs, 2026 26-03_RS_Hypergraphs-R16_02 https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-03_RS_Hypergraphs_06.jpg Hypergraphs, 2026 Hypergraphs, 2026, by Phillip C. Reiner, is a 3D printed resin object. The work consists of closed globular forms generated from hypergraph rewriting rules. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-03_RS_Hypergraphs_05.jpg Hypergraphs, 2026 Hypergraphs, 2026, by Phillip C. Reiner, is a 3D printed resin object. The work consists of closed globular forms generated from hypergraph rewriting rules. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-03_RS_Hypergraphs_04.jpg Hypergraphs, 2026 Hypergraphs, 2026, by Phillip C. Reiner, is a 3D printed resin object. The work consists of closed globular forms generated from hypergraph rewriting rules. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-03_RS_Hypergraphs_03.jpg Hypergraphs, 2026 26-03_RS_Hypergraphs-R16_07 https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-03_RS_Hypergraphs_02.jpg Hypergraphs, 2026 26-03_RS_Hypergraphs-R16_06 https://protoctrl.com/legal/ https://protoctrl.com/portfolio/the-supercube-a-modular-system-for-periodic-and-bounded-assemblies-2026/ 2026-03-25T08:57:32+01:00 https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_01.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 The SuperCube unit. A Axonometric view of the initial paper model, showing the three-dimensional structure with hidden edges. B Front view showing one face with tetrahedral indentation https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_18.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Geometric study: assembly of irregular truncated cubes, with selected faces drawn as complete forms and others as frame structures https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_17.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Geometric design study: 16 x 8 x 1 periodic pattern where rotated SuperCubes are replaced by SuperVoidCubes, with coplanar faces merged to create continuous surfaces https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_16.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Assembly arranged according to rhombicosidodecahedral geometry using ring configurations. A Assembly of 12 rings with guiding outlines, grey indicating faces coplanar with square faces. B Single ring module of ten SuperCubes around one pentagonal face, grey showing boundary faces https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_15.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Configuration of 180 units arranged according to dodecahedral geometry. A Frontwithdodecahedral outline, grey highlighting edge-adjacent faces. B Pentagonal cluster of 15 SuperCubes forming one face, grey showing boundary faces between clusters https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_14.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Extended assembly following icosahedral geometry, composed of 300 identical units. A Front with icosahedral outline, grey highlighting edge-adjacent faces. B Triangular cluster of 15 SuperCubes forming one face, grey showing boundary faces between clusters https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_13.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 SuperCube arrangement within icosahedral symmetry. A Eight-cube cluster aligned with rhombic triacontahedron. Grey highlights coplanar faces. B Central projection showing aligned unit (right) and rotated unit (left), with alternating spherical triangles indicating fundamental domains https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_12.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 The SuperCubeSphere: 60 identical units organised in closed assembly. A Perspective view, B Front view aligned to three-cube grouping, C Front view aligned to four-cube grouping, D Front view aligned to five-cube grouping https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_11.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Eight-cube unified cluster, A Front view facing the four-cube cluster with thickened outlines distinguishing the three constituent components, B side view, C top view, D perspective view https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_10.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Five SuperCubes in star-like formation. A Perspective view, B Front view with shaded areas illustrating void patterns seen from behind, C Side view https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_09.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Three-cube triangular assembly. A Perspective view, B Front view with shaded areas to illustrate void patterns seen from behind, C Top view https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_08.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Space-filling periodic assembly with 4 x 4 x 4 grid arrangement. A SuperCube modules, B Interior void volumes, C Interstitial void volumes, D Complete assembly combining ( A ), ( B ), and ( C ) https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_07.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Four SuperCubes arranged using matrices R 1 , R 3 , and R 4 . A Perspective view, B Front view with shaded areas to illustrate void patterns, C Top view https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_05.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Basic interlocking unit of two SuperCubes. A Perspective view with hidden tetrahedral interlocking, B Front view with grey shading indicating the interlocking area, C Side view https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_06.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Void volumes based on the rotated SuperCube. A Interior void volumes, B Interstitial void volumes, C Complete SuperVoidCube combining ( A ) and ( B ) https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_04.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Three-step SuperCube development from five-cube compound to final indented form. A Five-cube compound. B Two isolated cubes from compound. C Final SuperCube configuration. All three volumes share the same diagonal rotation axis https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_03.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Fuller's geometric observations from Synergetics. A T Quanta Module Foldable from Square (Figure 986.515) showing the folding sequence from square to tetrahedron. B T and E Modules: Minimod Nestabilities (Figure 986.561) showing fractal subdivision https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/26-02_EX_SuperCubePublication_02.jpg The SuperCube: A Modular System for Periodic and Bounded Assemblies, 2026 Unfolded net of the initial SuperCube paper model, reconstructed as a two-part pattern. Light grey and dark grey regions indicate the two groups of tetrahedral indentations. Interior lines within shaded areas form valley folds; perimeter lines create mountain folds. Each part forms three faces of the cubic envelope that fold into the complete unit https://protoctrl.com/legal/ https://protoctrl.com/portfolio/sea-art-festival-busan-2025-jeewi-lee-x-phillip-c-reiner/ 2026-03-25T08:57:32+01:00 https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_TidalMemories_01.jpg Sea Art Festival Busan, 2025 - Jeewi Lee x Phillip C. Reiner "Tidal Memories" by Jeewi Lee and Phillip C. Reiner consists of three 2-meter sculptures of sand grains enlarged 2000x. The works use data from Zeiss nano-CT scans to construct forms that sit at the Dadaepo Beach tide line. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_TidalMemories_05.jpg Sea Art Festival Busan, 2025 - Jeewi Lee x Phillip C. Reiner "Tidal Memories" by Jeewi Lee and Phillip C. Reiner consists of three 2-meter sculptures of sand grains enlarged 2000x. The works use data from Zeiss nano-CT scans to construct forms that sit at the Dadaepo Beach tide line. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_TidalMemories_04.jpg Sea Art Festival Busan, 2025 - Jeewi Lee x Phillip C. Reiner "Tidal Memories" by Jeewi Lee and Phillip C. Reiner consists of three 2-meter sculptures of sand grains enlarged 2000x. The works use data from Zeiss nano-CT scans to construct forms that sit at the Dadaepo Beach tide line. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_TidalMemories_03.jpg Sea Art Festival Busan, 2025 - Jeewi Lee x Phillip C. Reiner "Tidal Memories" by Jeewi Lee and Phillip C. Reiner consists of three 2-meter sculptures of sand grains enlarged 2000x. The works use data from Zeiss nano-CT scans to construct forms that sit at the Dadaepo Beach tide line. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_TidalMemories_02.jpg Sea Art Festival Busan, 2025 - Jeewi Lee x Phillip C. Reiner "Tidal Memories" by Jeewi Lee and Phillip C. Reiner consists of three 2-meter sculptures of sand grains enlarged 2000x. The works use data from Zeiss nano-CT scans to construct forms that sit at the Dadaepo Beach tide line. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/festival-of-future-nows-2025-jeewi-lee-x-phillip-c-reiner/ 2026-03-25T08:57:31+01:00 https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_FestivalOfFuturesNow_01.jpg Festival of Future Nows, 2025 - Jeewi Lee x Phillip C. Reiner "Fragment-Proximity_Sa-Ràpita_23-41" is a 3D-printed sand sculpture by Jeewi Lee and Phillip C. Reiner. It shows a Mallorca sand grain enlarged 1000 times via nano-CT scanning. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_FestivalOfFuturesNow_08.jpg Festival of Future Nows, 2025 - Jeewi Lee x Phillip C. Reiner "Fragment-Proximity_Sa-Ràpita_23-41" is a 3D-printed sand sculpture by Jeewi Lee and Phillip C. Reiner. It shows a Mallorca sand grain enlarged 1000 times via nano-CT scanning. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_FestivalOfFuturesNow_07.jpg Festival of Future Nows, 2025 - Jeewi Lee x Phillip C. Reiner "Fragment-Proximity_Sa-Ràpita_23-41" is a 3D-printed sand sculpture by Jeewi Lee and Phillip C. Reiner. It shows a Mallorca sand grain enlarged 1000 times via nano-CT scanning. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_FestivalOfFuturesNow_06.jpg Festival of Future Nows, 2025 - Jeewi Lee x Phillip C. Reiner "Fragment-Proximity_Sa-Ràpita_23-41" is a 3D-printed sand sculpture by Jeewi Lee and Phillip C. Reiner. It shows a Mallorca sand grain enlarged 1000 times via nano-CT scanning. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_FestivalOfFuturesNow_05.jpg Festival of Future Nows, 2025 - Jeewi Lee x Phillip C. Reiner "Fragment-Proximity_Sa-Ràpita_23-41" is a 3D-printed sand sculpture by Jeewi Lee and Phillip C. Reiner. It shows a Mallorca sand grain enlarged 1000 times via nano-CT scanning. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_FestivalOfFuturesNow_04.jpg Festival of Future Nows, 2025 - Jeewi Lee x Phillip C. Reiner "Fragment-Proximity_Sa-Ràpita_23-41" is a 3D-printed sand sculpture by Jeewi Lee and Phillip C. Reiner. It shows a Mallorca sand grain enlarged 1000 times via nano-CT scanning. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_FestivalOfFuturesNow_03.jpg Festival of Future Nows, 2025 - Jeewi Lee x Phillip C. Reiner "Fragment-Proximity_Sa-Ràpita_23-41" is a 3D-printed sand sculpture by Jeewi Lee and Phillip C. Reiner. It shows a Mallorca sand grain enlarged 1000 times via nano-CT scanning. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-09_EX_FestivalOfFuturesNow_02.jpg Festival of Future Nows, 2025 - Jeewi Lee x Phillip C. Reiner "Fragment-Proximity_Sa-Ràpita_23-41" is a 3D-printed sand sculpture by Jeewi Lee and Phillip C. Reiner. It shows a Mallorca sand grain enlarged 1000 times via nano-CT scanning. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/segment_popenguine_23-02-hsd-edition-2025-jeewi-lee-x-phillip-c-reiner/ 2026-03-25T08:57:30+01:00 https://protoctrl.com/wp-content/uploads/2026/03/25-07_JL_FragmentHSDEdition_01.jpg Segment_Popenguine_23-02 (HSD-Edition), 2025 - Jeewi Lee x Phillip C. Reiner "Fragment" (2025) by Jeewi Lee and Phillip C. Reiner is a screenprint on paper. It uses DICOM scan data and embeds actual sand particles from Popenguine, Senegal, into the print surface. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/bridges-conference-eindhoven-2025/ 2026-03-25T12:06:59+01:00 https://protoctrl.com/wp-content/uploads/2026/03/25-05_EX_BridgesPorouhedron_01.jpg Bridges Conference Eindhoven, 2025 Porouhedrons by Phillip C. Reiner are 3D-printed polyhedral models with systematic perforations. The work includes two configurations, #6 and #141, which display void networks within geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-05_EX_BridgesPorouhedron_02.jpg Bridges Conference Eindhoven, 2025 Porouhedrons by Phillip C. Reiner are 3D-printed polyhedral models with systematic perforations. The work includes two configurations, #6 and #141, which display void networks within geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/intersections-2025/ 2026-03-25T08:57:13+01:00 https://protoctrl.com/wp-content/uploads/2026/03/25-03_EX_SeattleMuseum_01.jpg Intersections, 2025 Dandelion Sphere No.15 (2025) by Phillip C. Reiner is a five-layer polyhedral framework made of 3D-printed polyamide. The piece sits in the Intersections exhibition at the Seattle Universal Math Museum. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/porouhedrons-2025/ 2026-03-25T12:06:30+01:00 https://protoctrl.com/wp-content/uploads/2026/03/25-02_RS_Porouhedrons_01.jpg Porouhedrons, 2025 Porouhedrons (2025) by Phillip C. Reiner is a series of 3D printed resin polyhedra. The works use algorithmic perforation to create porous structures with varying void densities. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-02_RS_Porouhedrons_03.jpg Porouhedrons, 2025 Porouhedrons (2025) by Phillip C. Reiner is a series of 3D printed resin polyhedra. The works use algorithmic perforation to create porous structures with varying void densities. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/25-02_RS_Porouhedrons_02.jpg Porouhedrons, 2025 Porouhedrons (2025) by Phillip C. Reiner is a series of 3D printed resin polyhedra. The works use algorithmic perforation to create porous structures with varying void densities. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/sand-fragments-motion-2024-jeewi-lee-x-phillip-c-reiner/ 2026-03-25T08:57:11+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-12_EX_FieldOfFragmentsShowroom_01.jpg Sand - Fragments - Motion, 2024 - Jeewi Lee x Phillip C. Reiner Sand - Fragments - Motion (2024) by Jeewi Lee consists of three 3D-printed sand sculptures on a white pedestal. The works are enlarged 130-500x replicas of nano-CT scanned sand grains. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-12_EX_FieldOfFragmentsShowroom_03.jpg Sand - Fragments - Motion, 2024 - Jeewi Lee x Phillip C. Reiner Sand - Fragments - Motion (2024) by Jeewi Lee consists of three 3D-printed sand sculptures on a white pedestal. The works are enlarged 130-500x replicas of nano-CT scanned sand grains. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-12_EX_FieldOfFragmentsShowroom_02.jpg Sand - Fragments - Motion, 2024 - Jeewi Lee x Phillip C. Reiner Sand - Fragments - Motion (2024) by Jeewi Lee consists of three 3D-printed sand sculptures on a white pedestal. The works are enlarged 130-500x replicas of nano-CT scanned sand grains. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/field-of-fragments-2024-jeewi-lee-x-phillip-c-reiner/ 2026-03-25T08:57:11+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_01.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_11.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_10.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_09.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_08.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_07.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_06.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_05.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_04.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_03.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-11_EX_FieldOfFragments_02.jpg Field of Fragments, 2024 - Jeewi Lee x Phillip C. Reiner Field of Fragments (2024) by Jeewi Lee and Phillip C. Reiner consists of 3D-printed sand sculptures and sand paintings. The works range from 100x to 1000x enlarged grains collected from six continents. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/model-for-your-circular-city-2024-studio-olafur-eliasson/ 2026-03-25T08:57:10+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-06_OE_ModelForYourCircularCity_01.jpg Model for your circular city, 2024 - Studio Olafur Eliasson Model for your circular city (2024) by Studio Olafur Eliasson uses a 440 cm high, 360 cm diameter wooden table to display geometric models by Phillip C. Reiner and Einar Thorsteinn. The work arranges physical maquettes and prototypes from 2015-2022 in a circular configuration. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-06_OE_ModelForYourCircularCity_05.jpg Model for your circular city, 2024 - Studio Olafur Eliasson Model for your circular city (2024) by Studio Olafur Eliasson uses a 440 cm high, 360 cm diameter wooden table to display geometric models by Phillip C. Reiner and Einar Thorsteinn. The work arranges physical maquettes and prototypes from 2015-2022 in a circular configuration. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-06_OE_ModelForYourCircularCity_04.jpg Model for your circular city, 2024 - Studio Olafur Eliasson Model for your circular city (2024) by Studio Olafur Eliasson uses a 440 cm high, 360 cm diameter wooden table to display geometric models by Phillip C. Reiner and Einar Thorsteinn. The work arranges physical maquettes and prototypes from 2015-2022 in a circular configuration. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-06_OE_ModelForYourCircularCity_03.jpg Model for your circular city, 2024 - Studio Olafur Eliasson Model for your circular city (2024) by Studio Olafur Eliasson uses a 440 cm high, 360 cm diameter wooden table to display geometric models by Phillip C. Reiner and Einar Thorsteinn. The work arranges physical maquettes and prototypes from 2015-2022 in a circular configuration. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-06_OE_ModelForYourCircularCity_02.jpg Model for your circular city, 2024 - Studio Olafur Eliasson Model for your circular city (2024) by Studio Olafur Eliasson uses a 440 cm high, 360 cm diameter wooden table to display geometric models by Phillip C. Reiner and Einar Thorsteinn. The work arranges physical maquettes and prototypes from 2015-2022 in a circular configuration. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/the-curious-planet-2024-olafur-eliasson/ 2026-03-25T08:57:09+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-06_OE_CuriousPlanet_01.jpg The Curious Planet, 2024 - Olafur Eliasson The Curious Planet (2024) by Studio Olafur Eliasson is a large-scale spherical sculpture at the Mulva Cultural Center. It uses segmented panels arranged by a consistent geometric rule for outdoor durability. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/bridges-conference-sydney-2024/ 2026-03-25T08:57:09+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-05_EX_BridgesQuantaMill_01.jpg Bridges Conference Sydney, 2024 A-QuantaMill by Phillip C. Reiner is a 3D-printed plaster model with epoxy coating. The object displays an octahedral arrangement of tetrahedral quanta modules. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-05_EX_BridgesTriakaleidocycloid_01.jpg Bridges Conference Sydney, 2024 Triakaleidocycloid by Phillip C. Reiner is a 3D-printed ABS object. It combines arcs and lines to form a developable surface. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/kaleidograins-2024/ 2026-03-25T14:34:27+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-04_RS_Kaleidograins_01_1920.jpg Kaleidograins, 2024 Kaleidograins (2024) by Phillip C. Reiner is a 3D printed resin kinetic sculpture. It projects sand grain surface structures onto rotating kaleidocycle frameworks. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-04_RS_Kaleidograins_05_1920.jpg Kaleidograins, 2024 Kaleidograins (2024) by Phillip C. Reiner is a 3D printed resin kinetic sculpture. It projects sand grain surface structures onto rotating kaleidocycle frameworks. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-04_RS_Kaleidograins_04_1920.jpg Kaleidograins, 2024 Kaleidograins (2024) by Phillip C. Reiner is a 3D printed resin kinetic sculpture. It projects sand grain surface structures onto rotating kaleidocycle frameworks. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-04_RS_Kaleidograins_03_1920.jpg Kaleidograins, 2024 Kaleidograins (2024) by Phillip C. Reiner is a 3D printed resin kinetic sculpture. It projects sand grain surface structures onto rotating kaleidocycle frameworks. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-04_RS_Kaleidograins_02_1920.jpg Kaleidograins, 2024 Kaleidograins (2024) by Phillip C. Reiner is a 3D printed resin kinetic sculpture. It projects sand grain surface structures onto rotating kaleidocycle frameworks. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/fragments-proximity-2024-jeewi-lee-x-phillip-c-reiner/ 2026-03-25T08:57:07+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_FragmentsProximity_01.jpg Fragments Proximity, 2024 - Jeewi Lee x Phillip C. Reiner Fragments Proximity (2024) by Jeewi Lee and Phillip C. Reiner consists of three sculptures. Each piece is a single sand grain enlarged 600 to 850 times using nano-CT scans and parametric modeling. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_FragmentsProximity_03.jpg Fragments Proximity, 2024 - Jeewi Lee x Phillip C. Reiner Fragments Proximity (2024) by Jeewi Lee and Phillip C. Reiner consists of three sculptures. Each piece is a single sand grain enlarged 600 to 850 times using nano-CT scans and parametric modeling. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_FragmentsProximity_02.jpg Fragments Proximity, 2024 - Jeewi Lee x Phillip C. Reiner Fragments Proximity (2024) by Jeewi Lee and Phillip C. Reiner consists of three sculptures. Each piece is a single sand grain enlarged 600 to 850 times using nano-CT scans and parametric modeling. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/nano-ct-2024/ 2026-03-25T14:20:53+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-01_RS_NanoCT_01_1920.jpg Nano-CT, 2024 Nano-CT (2024) by Phillip C. Reiner is a 3D printed resin object at protoCtrl, Berlin. It uses Zeiss X-ray microscopy and computational meshing to replicate sand grain topologies. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_RS_NanoCT_08_1920.jpg Nano-CT, 2024 Nano-CT (2024) by Phillip C. Reiner is a 3D printed resin object at protoCtrl, Berlin. It uses Zeiss X-ray microscopy and computational meshing to replicate sand grain topologies. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_RS_NanoCT_07_1920.jpg Nano-CT, 2024 Nano-CT (2024) by Phillip C. Reiner is a 3D printed resin object at protoCtrl, Berlin. It uses Zeiss X-ray microscopy and computational meshing to replicate sand grain topologies. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_RS_NanoCT_06_1920.jpg Nano-CT, 2024 Nano-CT (2024) by Phillip C. Reiner is a 3D printed resin object at protoCtrl, Berlin. It uses Zeiss X-ray microscopy and computational meshing to replicate sand grain topologies. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_RS_NanoCT_05_1920.jpg Nano-CT, 2024 Nano-CT (2024) by Phillip C. Reiner is a 3D printed resin object at protoCtrl, Berlin. It uses Zeiss X-ray microscopy and computational meshing to replicate sand grain topologies. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_RS_NanoCT_04_1920.jpg Nano-CT, 2024 Nano-CT (2024) by Phillip C. Reiner is a 3D printed resin object at protoCtrl, Berlin. It uses Zeiss X-ray microscopy and computational meshing to replicate sand grain topologies. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_RS_NanoCT_03_1920.jpg Nano-CT, 2024 Nano-CT (2024) by Phillip C. Reiner is a 3D printed resin object at protoCtrl, Berlin. It uses Zeiss X-ray microscopy and computational meshing to replicate sand grain topologies. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_RS_NanoCT_02_1920.jpg Nano-CT, 2024 Nano-CT (2024) by Phillip C. Reiner is a 3D printed resin object at protoCtrl, Berlin. It uses Zeiss X-ray microscopy and computational meshing to replicate sand grain topologies. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/fragments-2024-jeewi-lee-x-phillip-c-reiner/ 2026-03-25T08:57:06+01:00 https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_01.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_09.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_08.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_06.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_07.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_05.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_04.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_03.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/24-01_JL_Fragments_02.jpg Fragments, 2024 - Jeewi Lee x Phillip C. Reiner "Fragments" (2024) by Jeewi Lee and Phillip C. Reiner comprises nine enlarged sand grains. The works use 3D printing based on nano-CT scans to scale single grains 130 to 230 times. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/probability-of-conscious-gravitation-2023-olafur-eliasson/ 2026-03-25T08:57:05+01:00 https://protoctrl.com/wp-content/uploads/2026/03/23-03_OE_ProbabilityOfConscious_01.jpg Probability of conscious gravitation, 2023 - Olafur Eliasson Probability of conscious gravitation (2023) by Studio Olafur Eliasson is an installation of painted polyhedral and compound geometric elements. The work uses phi-based geometry to map probability distributions onto spatial positions. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/23-03_OE_ProbabilityOfConscious_03.jpg Probability of conscious gravitation, 2023 - Olafur Eliasson Probability of conscious gravitation (2023) by Studio Olafur Eliasson is an installation of painted polyhedral and compound geometric elements. The work uses phi-based geometry to map probability distributions onto spatial positions. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/23-03_OE_ProbabilityOfConscious_02.jpg Probability of conscious gravitation, 2023 - Olafur Eliasson Probability of conscious gravitation (2023) by Studio Olafur Eliasson is an installation of painted polyhedral and compound geometric elements. The work uses phi-based geometry to map probability distributions onto spatial positions. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/hopf-fibrations-2022/ 2026-03-25T08:57:04+01:00 https://protoctrl.com/wp-content/uploads/2026/03/22-05_RS_HopfFibrations_01.jpg Hopf Fibrations, 2022 Hopf Fibrations (2022) by Phillip C. Reiner is a 3D printed resin model of four-dimensional topology. The object shows interlocking curves derived from stereographic projection of the 3-sphere. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-05_RS_HopfFibrations_03.jpg Hopf Fibrations, 2022 Hopf Fibrations (2022) by Phillip C. Reiner is a 3D printed resin model of four-dimensional topology. The object shows interlocking curves derived from stereographic projection of the 3-sphere. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-05_RS_HopfFibrations_02.jpg Hopf Fibrations, 2022 Hopf Fibrations (2022) by Phillip C. Reiner is a 3D printed resin model of four-dimensional topology. The object shows interlocking curves derived from stereographic projection of the 3-sphere. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/bridges-conference-helsinki-2022-stefano-arrighi-x-phillip-c-reiner/ 2026-03-25T08:57:04+01:00 https://protoctrl.com/wp-content/uploads/2026/03/22-05_EX_SeaStellation_01.jpg Bridges Conference Helsinki, 2022 - Stefano Arrighi x Phillip C. Reiner Sea Stellation by Stefano Arrighi and Phillip C. Reiner is a 3D-printed plaster model of a deformed rhombic triacontahedron stellation. The object was fabricated for the 2022 Bridges Conference in Helsinki. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/bridges-conference-helsinki-2022/ 2026-03-25T08:57:03+01:00 https://protoctrl.com/wp-content/uploads/2026/03/22-05_EX_BridgesAperiodicGradient_01.jpg Bridges Conference Helsinki, 2022 Aperiodic Gradient by Phillip C. Reiner is a c-print on paper in a wooden frame. The work uses machine learning to cull points from a cloud, creating a non-repetitive gradient. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/the-attention-of-time-2022-olafur-eliasson/ 2026-03-25T08:57:02+01:00 https://protoctrl.com/wp-content/uploads/2026/03/22-04_OE_AttentionOfTime_01.jpg The Attention of Time, 2022 - Olafur Eliasson The Attention of Time (2022) is an installation by Studio Olafur Eliasson. It uses partially silvered glass spheres, cyan and black paint, and stainless steel to create reflections that shift with viewer position. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_OE_AttentionOfTime_03.jpg The Attention of Time, 2022 - Olafur Eliasson The Attention of Time (2022) is an installation by Studio Olafur Eliasson. It uses partially silvered glass spheres, cyan and black paint, and stainless steel to create reflections that shift with viewer position. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_OE_AttentionOfTime_02.jpg The Attention of Time, 2022 - Olafur Eliasson The Attention of Time (2022) is an installation by Studio Olafur Eliasson. It uses partially silvered glass spheres, cyan and black paint, and stainless steel to create reflections that shift with viewer position. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/journey-of-circumference-2025-thilo-frank-x-phillip-c-reiner/ 2026-03-25T08:57:02+01:00 https://protoctrl.com/wp-content/uploads/2026/03/22-04_TF_JourneyOfCircumference_01.jpg Journey of Circumference, 2025 - Thilo Frank x Phillip C. Reiner Journey of Circumference (2025) is an outdoor installation of eleven elements made of painted stainless steel, wood, and lighting. The pieces range from 0.8 to 4.4 meters in diameter and sit at Woodhub, Odense. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_TF_JourneyOfCircumference_08.jpg Journey of Circumference, 2025 - Thilo Frank x Phillip C. Reiner Journey of Circumference (2025) is an outdoor installation of eleven elements made of painted stainless steel, wood, and lighting. The pieces range from 0.8 to 4.4 meters in diameter and sit at Woodhub, Odense. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_TF_JourneyOfCircumference_07.jpg Journey of Circumference, 2025 - Thilo Frank x Phillip C. Reiner Journey of Circumference (2025) is an outdoor installation of eleven elements made of painted stainless steel, wood, and lighting. The pieces range from 0.8 to 4.4 meters in diameter and sit at Woodhub, Odense. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_TF_JourneyOfCircumference_06.jpg Journey of Circumference, 2025 - Thilo Frank x Phillip C. Reiner Journey of Circumference (2025) is an outdoor installation of eleven elements made of painted stainless steel, wood, and lighting. The pieces range from 0.8 to 4.4 meters in diameter and sit at Woodhub, Odense. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_TF_JourneyOfCircumference_05.jpg Journey of Circumference, 2025 - Thilo Frank x Phillip C. Reiner Journey of Circumference (2025) is an outdoor installation of eleven elements made of painted stainless steel, wood, and lighting. The pieces range from 0.8 to 4.4 meters in diameter and sit at Woodhub, Odense. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_TF_JourneyOfCircumference_04.jpg Journey of Circumference, 2025 - Thilo Frank x Phillip C. Reiner Journey of Circumference (2025) is an outdoor installation of eleven elements made of painted stainless steel, wood, and lighting. The pieces range from 0.8 to 4.4 meters in diameter and sit at Woodhub, Odense. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_TF_JourneyOfCircumference_03.jpg Journey of Circumference, 2025 - Thilo Frank x Phillip C. Reiner Journey of Circumference (2025) is an outdoor installation of eleven elements made of painted stainless steel, wood, and lighting. The pieces range from 0.8 to 4.4 meters in diameter and sit at Woodhub, Odense. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-04_TF_JourneyOfCircumference_02.jpg Journey of Circumference, 2025 - Thilo Frank x Phillip C. Reiner Journey of Circumference (2025) is an outdoor installation of eleven elements made of painted stainless steel, wood, and lighting. The pieces range from 0.8 to 4.4 meters in diameter and sit at Woodhub, Odense. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/platonic-compounds-2022/ 2026-03-25T08:57:01+01:00 https://protoctrl.com/wp-content/uploads/2026/03/22-01_RS_PlatonicCompounds_01.jpg Platonic Compounds, 2022 Platonic Compounds (2022) by Phillip C. Reiner is a 3D printed resin study of nested Platonic solids. The work documents geometric configurations where regular polyhedra share a common center or stack vertically. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-01_RS_PlatonicCompounds_05.jpg Platonic Compounds, 2022 Platonic Compounds (2022) by Phillip C. Reiner is a 3D printed resin study of nested Platonic solids. The work documents geometric configurations where regular polyhedra share a common center or stack vertically. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-01_RS_PlatonicCompounds_04.jpg Platonic Compounds, 2022 Platonic Compounds (2022) by Phillip C. Reiner is a 3D printed resin study of nested Platonic solids. The work documents geometric configurations where regular polyhedra share a common center or stack vertically. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-01_RS_PlatonicCompounds_03.jpg Platonic Compounds, 2022 Platonic Compounds (2022) by Phillip C. Reiner is a 3D printed resin study of nested Platonic solids. The work documents geometric configurations where regular polyhedra share a common center or stack vertically. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/22-01_RS_PlatonicCompounds_02.jpg Platonic Compounds, 2022 Platonic Compounds (2022) by Phillip C. Reiner is a 3D printed resin study of nested Platonic solids. The work documents geometric configurations where regular polyhedra share a common center or stack vertically. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/your-submerged-spectator-2021-olafur-eliasson/ 2026-03-25T08:57:00+01:00 https://protoctrl.com/wp-content/uploads/2026/03/21-06_OE_YourSubmergedSpectator_01.jpg Your Submerged Spectator, 2021 - Olafur Eliasson Your Submerged Spectator (2021) by Studio Olafur Eliasson consists of seven Carrara marble blocks suspended by stainless steel in the Kunsthaus Zürich tunnel. The works are CNC-milled from 3D scans of ice collected from Diamond Beach, Iceland. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/21-06_OE_YourSubmergedSpectator_03.jpg Your Submerged Spectator, 2021 - Olafur Eliasson Your Submerged Spectator (2021) by Studio Olafur Eliasson consists of seven Carrara marble blocks suspended by stainless steel in the Kunsthaus Zürich tunnel. The works are CNC-milled from 3D scans of ice collected from Diamond Beach, Iceland. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/21-06_OE_YourSubmergedSpectator_02.jpg Your Submerged Spectator, 2021 - Olafur Eliasson Your Submerged Spectator (2021) by Studio Olafur Eliasson consists of seven Carrara marble blocks suspended by stainless steel in the Kunsthaus Zürich tunnel. The works are CNC-milled from 3D scans of ice collected from Diamond Beach, Iceland. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/bridges-conference-virtual-2021-stefano-arrighi-x-phillip-c-reiner/ 2026-03-25T08:56:21+01:00 https://protoctrl.com/wp-content/uploads/2026/03/21-05_EX_DandelionSphere_01.jpg Bridges Conference (Virtual), 2021 - Stefano Arrighi x Phillip C. Reiner Dandelion Sphere (2021) by Stefano Arrighi and Phillip C. Reiner is a layered polyhedral framework of 3D-printed connectors and wood. The structure uses node-classification algorithms to generate automated joints for its complex wireframe shells. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/bridges-conference-virtual-2021/ 2026-03-25T08:56:21+01:00 https://protoctrl.com/wp-content/uploads/2026/03/21-05_EX_BridgesAperiodicSubgrouping_01.jpg Bridges Conference (Virtual), 2021 Bridges Conference (Virtual), 2021 by Phillip C. Reiner is a 3D-printed resin model of aperiodic subgrouping. It has five subgroups and ten tilted tile types that reflect sunlight. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/kaleidosphere-2020-olafur-eliasson/ 2026-03-25T08:56:20+01:00 https://protoctrl.com/wp-content/uploads/2026/03/20-08_OE_Kaleidosphere_01.jpg Kaleidosphere, 2020 - Olafur Eliasson Kaleidosphere (2020) by Studio Olafur Eliasson is a spherical sculpture containing thirty kaleidoscopes. It uses stainless steel, mirrors, glass, and 3D prints mounted in a rotatable frame. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-08_OE_Kaleidosphere_03.jpg Kaleidosphere, 2020 - Olafur Eliasson Kaleidosphere (2020) by Studio Olafur Eliasson is a spherical sculpture containing thirty kaleidoscopes. It uses stainless steel, mirrors, glass, and 3D prints mounted in a rotatable frame. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-08_OE_Kaleidosphere_02.jpg Kaleidosphere, 2020 - Olafur Eliasson Kaleidosphere (2020) by Studio Olafur Eliasson is a spherical sculpture containing thirty kaleidoscopes. It uses stainless steel, mirrors, glass, and 3D prints mounted in a rotatable frame. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/ice-scans-2020/ 2026-03-25T08:56:19+01:00 https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_01.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_10.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_09.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_08.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_07.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_06.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_05.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_04.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_03.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/20-07_RS_IceScans_02.jpg Ice Scans, 2020 Ice Scans (2020) by Phillip C. Reiner is a 3D printed resin work. It uses laser scanning to capture melting ice geometry for additive manufacturing. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/bridges-conference-virtual-2020/ 2026-03-25T08:56:19+01:00 https://protoctrl.com/wp-content/uploads/2026/03/20-05_EX_BridgesKaleidosphere_01.jpg Bridges Conference (Virtual), 2020 Kaleidosphere by Phillip C. Reiner is a 2020 prototype of stainless steel and 3D printed resin. It combines polyhedral sections with mirror surfaces to form a spherical geometry. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/human-time-is-movement-2019-olafur-eliasson/ 2026-03-25T08:56:18+01:00 https://protoctrl.com/wp-content/uploads/2026/03/19-06_OE_HumanTime_01.jpg Human Time is Movement, 2019 - Olafur Eliasson Human Time is Movement (2019) by Studio Olafur Eliasson is a stainless steel sculpture painted black and white. The work uses a Clelia curve form created by varying rotation speeds and contraction factors. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/19-06_OE_HumanTime_04.jpg Human Time is Movement, 2019 - Olafur Eliasson Human Time is Movement (2019) by Studio Olafur Eliasson is a stainless steel sculpture painted black and white. The work uses a Clelia curve form created by varying rotation speeds and contraction factors. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/19-06_OE_HumanTime_03.jpg Human Time is Movement, 2019 - Olafur Eliasson Human Time is Movement (2019) by Studio Olafur Eliasson is a stainless steel sculpture painted black and white. The work uses a Clelia curve form created by varying rotation speeds and contraction factors. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/19-06_OE_HumanTime_02.jpg Human Time is Movement, 2019 - Olafur Eliasson Human Time is Movement (2019) by Studio Olafur Eliasson is a stainless steel sculpture painted black and white. The work uses a Clelia curve form created by varying rotation speeds and contraction factors. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/atm-sphere-2019/ 2026-03-25T08:56:17+01:00 https://protoctrl.com/wp-content/uploads/2026/03/19-05_RS_AtmSphere_01.jpg Atm Sphere, 2019 Atm Sphere (2019) by Phillip C. Reiner is a 3D printed resin model. It uses triangular panels to reflect light twice from a central source, creating a glowing shell without direct visibility of the light. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/the-planet-spins-despite-me-stopping-2018-olafur-eliasson/ 2026-03-25T08:56:16+01:00 https://protoctrl.com/wp-content/uploads/2026/03/18-09_OE_PlanetSpins_01.jpg The Planet Spins Despite Me Stopping, 2018 - Olafur Eliasson The Planet Spins Despite Me Stopping (2018) is a static stainless steel spiral. The work uses a parametric curve to create an illusion of rotation as the viewer moves. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/18-09_OE_PlanetSpins_03.jpg The Planet Spins Despite Me Stopping, 2018 - Olafur Eliasson The Planet Spins Despite Me Stopping (2018) is a static stainless steel spiral. The work uses a parametric curve to create an illusion of rotation as the viewer moves. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/18-09_OE_PlanetSpins_02.jpg The Planet Spins Despite Me Stopping, 2018 - Olafur Eliasson The Planet Spins Despite Me Stopping (2018) is a static stainless steel spiral. The work uses a parametric curve to create an illusion of rotation as the viewer moves. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/how-to-build-a-sphere-out-of-cubes-2018-olafur-eliasson/ 2026-03-25T08:56:16+01:00 https://protoctrl.com/wp-content/uploads/2026/03/18-07_OE_HowToBuildSphere_01.jpg How to Build a Sphere Out of Cubes, 2018 - Olafur Eliasson How to Build a Sphere Out of Cubes (2018) by Studio Olafur Eliasson consists of two stainless steel mirror structures with integrated lighting. A human-sized cube and a pavilion-scale stellated polyhedron of sixty modules sit on an elliptical lawn at Texas A&M University. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/space-fillings-2018/ 2026-03-25T08:56:15+01:00 https://protoctrl.com/wp-content/uploads/2026/03/18-04_RS_SpaceFillings_01.jpg Space Fillings, 2018 Space Fillings (2018) by Phillip C. Reiner is a 3D printed resin assembly of polyhedra. The work sits in Studio Olafur Eliasson, Berlin, and shows geometric tiling patterns. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/18-04_RS_SpaceFillings_04.jpg Space Fillings, 2018 Space Fillings (2018) by Phillip C. Reiner is a 3D printed resin assembly of polyhedra. The work sits in Studio Olafur Eliasson, Berlin, and shows geometric tiling patterns. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/18-04_RS_SpaceFillings_03.jpg Space Fillings, 2018 Space Fillings (2018) by Phillip C. Reiner is a 3D printed resin assembly of polyhedra. The work sits in Studio Olafur Eliasson, Berlin, and shows geometric tiling patterns. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/fjordenhus-2009-2018-olafur-eliasson/ 2026-03-25T08:56:14+01:00 https://protoctrl.com/wp-content/uploads/2026/03/18-03_OE_Fjordenhus_01.jpg Fjordenhus, 2009-2018 - Olafur Eliasson Fjordenhus (2009-2018) by Studio Olafur Eliasson is a 28-meter brick building in Vejle, Denmark. It consists of four intersecting cylinders with subtracted ellipsoidal volumes forming curved facades and arched windows. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/18-03_OE_Fjordenhus_02.jpg Fjordenhus, 2009-2018 - Olafur Eliasson Fjordenhus (2009-2018) by Studio Olafur Eliasson is a 28-meter brick building in Vejle, Denmark. It consists of four intersecting cylinders with subtracted ellipsoidal volumes forming curved facades and arched windows. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/parabol-stars-2018/ 2026-03-25T08:56:14+01:00 https://protoctrl.com/wp-content/uploads/2026/03/18-02_RS_ParabolStars_01.jpg Parabol Stars, 2018 Parabol Stars (2018) by Phillip C. Reiner is a 3D printed resin structure with parabolic mirrors on polyhedral faces. The work uses a node connector system to align focal points for light cones. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/18-02_RS_ParabolStars_04.jpg Parabol Stars, 2018 Parabol Stars (2018) by Phillip C. Reiner is a 3D printed resin structure with parabolic mirrors on polyhedral faces. The work uses a node connector system to align focal points for light cones. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/18-02_RS_ParabolStars_03.jpg Parabol Stars, 2018 Parabol Stars (2018) by Phillip C. Reiner is a 3D printed resin structure with parabolic mirrors on polyhedral faces. The work uses a node connector system to align focal points for light cones. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/18-02_RS_ParabolStars_02.jpg Parabol Stars, 2018 Parabol Stars (2018) by Phillip C. Reiner is a 3D printed resin structure with parabolic mirrors on polyhedral faces. The work uses a node connector system to align focal points for light cones. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/moon-sphere-2017/ 2026-03-25T08:56:13+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-12_RS_MoonSphere_01.jpg Moon Sphere, 2017 Moon Sphere, 2017, by Phillip C. Reiner, is a 3D printed resin model mapping lunar topography onto polyhedral forms using NASA data and node connectors. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-12_RS_MoonSphere_03.jpg Moon Sphere, 2017 Moon Sphere, 2017, by Phillip C. Reiner, is a 3D printed resin model mapping lunar topography onto polyhedral forms using NASA data and node connectors. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-12_RS_MoonSphere_02.jpg Moon Sphere, 2017 Moon Sphere, 2017, by Phillip C. Reiner, is a 3D printed resin model mapping lunar topography onto polyhedral forms using NASA data and node connectors. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/molahedrons-2017/ 2026-03-25T08:56:12+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-11_RS_Molahedrons_01.jpg Molahedrons, 2017 Molahedrons (2017) by Phillip C. Reiner is a 3D printed resin object mapping Mars topography onto polyhedral forms using NASA orbiter data. The work projects planetary relief onto various three-dimensional geometric substrates. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-11_RS_Molahedrons_03.jpg Molahedrons, 2017 Molahedrons (2017) by Phillip C. Reiner is a 3D printed resin object mapping Mars topography onto polyhedral forms using NASA orbiter data. The work projects planetary relief onto various three-dimensional geometric substrates. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-11_RS_Molahedrons_02.jpg Molahedrons, 2017 Molahedrons (2017) by Phillip C. Reiner is a 3D printed resin object mapping Mars topography onto polyhedral forms using NASA orbiter data. The work projects planetary relief onto various three-dimensional geometric substrates. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/deep-sea-2017/ 2026-03-25T08:56:11+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-09_RS_DeepSea_01.jpg Deep Sea, 2017 Deep Sea (2017) by Phillip C. Reiner is a 3D printed resin study of stellated polyhedra. It shows simulated pressure deformation and structural collapse of geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-09_RS_DeepSea_05.jpg Deep Sea, 2017 Deep Sea (2017) by Phillip C. Reiner is a 3D printed resin study of stellated polyhedra. It shows simulated pressure deformation and structural collapse of geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-09_RS_DeepSea_04.jpg Deep Sea, 2017 Deep Sea (2017) by Phillip C. Reiner is a 3D printed resin study of stellated polyhedra. It shows simulated pressure deformation and structural collapse of geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-09_RS_DeepSea_03.jpg Deep Sea, 2017 Deep Sea (2017) by Phillip C. Reiner is a 3D printed resin study of stellated polyhedra. It shows simulated pressure deformation and structural collapse of geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-09_RS_DeepSea_02.jpg Deep Sea, 2017 Deep Sea (2017) by Phillip C. Reiner is a 3D printed resin study of stellated polyhedra. It shows simulated pressure deformation and structural collapse of geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/supercube-structures-2017/ 2026-03-25T08:56:12+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-09_RS_SuperCubeStructures_01.jpg SuperCube Structures, 2017 SuperCube Structures (2017) by Phillip C. Reiner is a 3D-printed resin assembly of triangular, pentagonal, and ring formations. The work combines multiple modular elements to test interconnection methods and spatial configurations. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-09_RS_SuperCubeStructures_02.jpg SuperCube Structures, 2017 SuperCube Structures (2017) by Phillip C. Reiner is a 3D-printed resin assembly of triangular, pentagonal, and ring formations. The work combines multiple modular elements to test interconnection methods and spatial configurations. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/supercube-spheres-2017/ 2026-03-25T14:25:56+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-08_RS_SuperCubeSpheres_02.jpg SuperCube Spheres, 2017 SuperCube Spheres, 2017, by Phillip C. Reiner. 3D printed resin model showing three-cube and five-cube clusters forming icosahedral and dodecahedral shapes. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/five-fold-maps-2017/ 2026-03-25T08:56:09+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-07_RS_FiveFoldMaps_01.jpg Five-Fold Maps, 2017 Five-Fold Maps, 2017, by Phillip C. Reiner, is a 3D printed resin model. It projects 2D aperiodic patterns onto icosahedral forms. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-07_RS_FiveFoldMaps_02.jpg Five-Fold Maps, 2017 Five-Fold Maps, 2017, by Phillip C. Reiner, is a 3D printed resin model. It projects 2D aperiodic patterns onto icosahedral forms. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/la-congiuntura-2017-olafur-eliasson/ 2026-03-25T08:56:09+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-06_OE_LaCongiuntura_01.jpg La Congiuntura, 2017 - Olafur Eliasson La Congiuntura (2017) by Studio Olafur Eliasson is a site-specific intervention at Castello di Rivoli. It uses geometric window elements based on SuperCube and phi-modular systems to alter existing openings without affecting the load-bearing structure. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-06_OE_LaCongiuntura_03.jpg La Congiuntura, 2017 - Olafur Eliasson La Congiuntura (2017) by Studio Olafur Eliasson is a site-specific intervention at Castello di Rivoli. It uses geometric window elements based on SuperCube and phi-modular systems to alter existing openings without affecting the load-bearing structure. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-06_OE_LaCongiuntura_02.jpg La Congiuntura, 2017 - Olafur Eliasson La Congiuntura (2017) by Studio Olafur Eliasson is a site-specific intervention at Castello di Rivoli. It uses geometric window elements based on SuperCube and phi-modular systems to alter existing openings without affecting the load-bearing structure. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/sonic-2019-thilo-frank-x-phillip-c-reiner/ 2026-03-25T08:54:58+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-06_TF_Sonic_01.jpg Sonic, 2019 - Thilo Frank x Phillip C. Reiner Sonic (2019) by Thilo Frank and Phillip C. Reiner is a rotating mirror assembly of coated stainless steel and time-controlled lighting mounted on a brick wall at Dansekapellet, Copenhagen. The work connects interior and exterior sight lines through a periscopic arrangement aligned with the courtyard axis. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-06_TF_Sonic_04.jpg Sonic, 2019 - Thilo Frank x Phillip C. Reiner Sonic (2019) by Thilo Frank and Phillip C. Reiner is a rotating mirror assembly of coated stainless steel and time-controlled lighting mounted on a brick wall at Dansekapellet, Copenhagen. The work connects interior and exterior sight lines through a periscopic arrangement aligned with the courtyard axis. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-06_TF_Sonic_03.jpg Sonic, 2019 - Thilo Frank x Phillip C. Reiner Sonic (2019) by Thilo Frank and Phillip C. Reiner is a rotating mirror assembly of coated stainless steel and time-controlled lighting mounted on a brick wall at Dansekapellet, Copenhagen. The work connects interior and exterior sight lines through a periscopic arrangement aligned with the courtyard axis. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-06_TF_Sonic_02.jpg Sonic, 2019 - Thilo Frank x Phillip C. Reiner Sonic (2019) by Thilo Frank and Phillip C. Reiner is a rotating mirror assembly of coated stainless steel and time-controlled lighting mounted on a brick wall at Dansekapellet, Copenhagen. The work connects interior and exterior sight lines through a periscopic arrangement aligned with the courtyard axis. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/bridges-conference-waterloo-2017/ 2026-03-25T08:54:57+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-05_EX_BridgesSuperCubeSphere_01.jpg Bridges Conference Waterloo, 2017 SuperCubeSphere by Phillip C. Reiner is a 3D-printed plaster model with epoxy coating. The object combines phi-tetrahedra to form a cube and spherical geometry based on the golden ratio. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-06_EX_BridgesInvertedSuperCubeSphere_01.jpg Bridges Conference Waterloo, 2017 InvertedSuperCubeSphere by Phillip C. Reiner is a 3D-printed plaster object coated in epoxy. The work uses phi-tetrahedra to form a cube-based geometry with golden-ratio subdivisions. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/supercube-walls-2017/ 2026-03-25T08:54:56+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-04_RS_SuperCubeWalls_01.jpg SuperCube Walls, 2017 SuperCube Walls, 2017, by Phillip C. Reiner, is a 3D printed resin study of periodic planar arrangements. It uses repeating four-cube blocks with strategic voids to form grid patterns. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-04_RS_SuperCubeWalls_02.jpg SuperCube Walls, 2017 SuperCube Walls, 2017, by Phillip C. Reiner, is a 3D printed resin study of periodic planar arrangements. It uses repeating four-cube blocks with strategic voids to form grid patterns. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/supercube-elements-2017/ 2026-03-25T08:54:56+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-02_RS_SuperCubeElements_01.jpg SuperCube Elements, 2017 SuperCube Elements (2017) by Phillip C. Reiner is a 3D printed resin model of interlocking cube clusters. It shows geometric assemblies ranging from two-cube pairs to ten-cube rings. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-02_RS_SuperCubeElements_02.jpg SuperCube Elements, 2017 SuperCube Elements (2017) by Phillip C. Reiner is a 3D printed resin model of interlocking cube clusters. It shows geometric assemblies ranging from two-cube pairs to ten-cube rings. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/phi-stars-2017/ 2026-03-25T14:35:58+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-02_RS_PhiStars_01.jpg Phi Stars, 2017 Phi Stars, 2017, by Phillip C. Reiner, is a 3D printed resin model. It combines T-Quanta modules in icosahedral symmetry to form fractal polyhedral structures. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-02_RS_PhiStars_03.jpg Phi Stars, 2017 Phi Stars, 2017, by Phillip C. Reiner, is a 3D printed resin model. It combines T-Quanta modules in icosahedral symmetry to form fractal polyhedral structures. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-02_RS_PhiStars_02.jpg Phi Stars, 2017 Phi Stars, 2017, by Phillip C. Reiner, is a 3D printed resin model. It combines T-Quanta modules in icosahedral symmetry to form fractal polyhedral structures. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/supercube-towers-2017/ 2026-03-25T08:54:54+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-01_RS_SuperCubeTowers_01.jpg SuperCube Towers, 2017 SuperCube Towers, 2017, by Phillip C. Reiner, is a 3D-printed resin model of stacked interlocking rings. The work sits in Studio Olafur Eliasson, Berlin, and shows vertical configurations of the SuperCube system. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-01_RS_SuperCubeTowers_02.jpg SuperCube Towers, 2017 SuperCube Towers, 2017, by Phillip C. Reiner, is a 3D-printed resin model of stacked interlocking rings. The work sits in Studio Olafur Eliasson, Berlin, and shows vertical configurations of the SuperCube system. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/kaleidocycloids-2017/ 2026-03-25T08:54:53+01:00 https://protoctrl.com/wp-content/uploads/2026/03/17-01_RS_Kaleidocycloids_01.jpg Kaleidocycloids, 2017 Kaleidocycloids (2017) by Phillip C. Reiner is a 3D printed resin kinetic polyhedral structure. Ring-shaped triangular modules connect via hinges to invert through continuous rotation. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-01_RS_Kaleidocycloids_04.jpg Kaleidocycloids, 2017 Kaleidocycloids (2017) by Phillip C. Reiner is a 3D printed resin kinetic polyhedral structure. Ring-shaped triangular modules connect via hinges to invert through continuous rotation. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-01_RS_Kaleidocycloids_03.jpg Kaleidocycloids, 2017 Kaleidocycloids (2017) by Phillip C. Reiner is a 3D printed resin kinetic polyhedral structure. Ring-shaped triangular modules connect via hinges to invert through continuous rotation. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/17-01_RS_Kaleidocycloids_02.jpg Kaleidocycloids, 2017 Kaleidocycloids (2017) by Phillip C. Reiner is a 3D printed resin kinetic polyhedral structure. Ring-shaped triangular modules connect via hinges to invert through continuous rotation. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/rotational-compounds-2016/ 2026-03-25T08:54:53+01:00 https://protoctrl.com/wp-content/uploads/2026/03/16-12_RS_RotationalCompounds_01.jpg Rotational Compounds, 2016 Rotational Compounds, 2016, by Phillip C. Reiner, is a 3D printed resin study of polyhedral forms. The work combines regular and rotational symmetry groups to create compound structures. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/rhombic-structures-2016/ 2026-03-25T08:54:52+01:00 https://protoctrl.com/wp-content/uploads/2026/03/16-12_RS_RhombicStructures_01.jpg Rhombic Structures, 2016 Rhombic Structures, 2016, by Phillip C. Reiner, is a 3D printed resin study of golden rhombohedra. The work shows spatial arrangements forming polyhedral forms and aperiodic tilings. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-12_RS_RhombicStructures_02.jpg Rhombic Structures, 2016 Rhombic Structures, 2016, by Phillip C. Reiner, is a 3D printed resin study of golden rhombohedra. The work shows spatial arrangements forming polyhedral forms and aperiodic tilings. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/crystal-loop-2017-thilo-frank-x-phillip-c-reiner/ 2026-03-25T08:54:51+01:00 https://protoctrl.com/wp-content/uploads/2026/03/16-11_TF_CrystalLoop_01.jpg Crystal Loop, 2017 - Thilo Frank x Phillip C. Reiner Crystal Loop (2017) by Thilo Frank and Phillip C. Reiner is a suspended installation of 36 coated stainless steel tetrahedra arranged along a Möbius strip. The structure hangs in the Rødovre Centrum atrium and uses a time-controlled lighting system. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-11_TF_CrystalLoop_03.jpg Crystal Loop, 2017 - Thilo Frank x Phillip C. Reiner Crystal Loop (2017) by Thilo Frank and Phillip C. Reiner is a suspended installation of 36 coated stainless steel tetrahedra arranged along a Möbius strip. The structure hangs in the Rødovre Centrum atrium and uses a time-controlled lighting system. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-11_TF_CrystalLoop_02.jpg Crystal Loop, 2017 - Thilo Frank x Phillip C. Reiner Crystal Loop (2017) by Thilo Frank and Phillip C. Reiner is a suspended installation of 36 coated stainless steel tetrahedra arranged along a Möbius strip. The structure hangs in the Rødovre Centrum atrium and uses a time-controlled lighting system. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/robotsphere-2016/ 2026-03-25T08:54:51+01:00 https://protoctrl.com/wp-content/uploads/2026/03/16-10_RS_RobotSphere_01.jpg RobotSphere, 2016 RobotSphere, 2016, by Phillip C. Reiner, is a 3D printed resin sculpture. It uses robotic tube bending to form spirals that transition from flat to a spherical double vortex. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-10_RS_RobotSphere_05.jpg RobotSphere, 2016 RobotSphere, 2016, by Phillip C. Reiner, is a 3D printed resin sculpture. It uses robotic tube bending to form spirals that transition from flat to a spherical double vortex. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-10_RS_RobotSphere_04.jpg RobotSphere, 2016 RobotSphere, 2016, by Phillip C. Reiner, is a 3D printed resin sculpture. It uses robotic tube bending to form spirals that transition from flat to a spherical double vortex. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-10_RS_RobotSphere_03.jpg RobotSphere, 2016 RobotSphere, 2016, by Phillip C. Reiner, is a 3D printed resin sculpture. It uses robotic tube bending to form spirals that transition from flat to a spherical double vortex. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-10_RS_RobotSphere_02.jpg RobotSphere, 2016 RobotSphere, 2016, by Phillip C. Reiner, is a 3D printed resin sculpture. It uses robotic tube bending to form spirals that transition from flat to a spherical double vortex. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/spherical-compounds-2016/ 2026-03-25T08:54:50+01:00 https://protoctrl.com/wp-content/uploads/2026/03/16-09_RS_SphericalCompounds_01.jpg Spherical Compounds, 2016 Spherical Compounds (2016) by Phillip C. Reiner is a 3D printed resin model of nested polyhedra on a spherical surface. The work uses radial arcs, wireframes, and continuous surfaces to combine multiple geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-09_RS_SphericalCompounds_02.jpg Spherical Compounds, 2016 Spherical Compounds (2016) by Phillip C. Reiner is a 3D printed resin model of nested polyhedra on a spherical surface. The work uses radial arcs, wireframes, and continuous surfaces to combine multiple geometric forms. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/multi-polar-sphere-2016/ 2026-03-25T08:54:49+01:00 https://protoctrl.com/wp-content/uploads/2026/03/16-03_RS_Multipolarsphere_01.jpg Multi-Polar Sphere, 2016 Multi-Polar Sphere (2016) by Phillip C. Reiner is a 3D printed resin sphere. It uses spiral paneling to map global wind patterns onto its surface. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/16-03_RS_Multipolarsphere_02.jpg Multi-Polar Sphere, 2016 Multi-Polar Sphere (2016) by Phillip C. Reiner is a 3D printed resin sphere. It uses spiral paneling to map global wind patterns onto its surface. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/less-ego-wall-2015-olafur-eliasson/ 2026-03-25T08:54:49+01:00 https://protoctrl.com/wp-content/uploads/2026/03/15-06_OE_LessEgoWall_01.jpg Less Ego Wall, 2015 - Olafur Eliasson Less Ego Wall (2015) by Studio Olafur Eliasson is a partition of stainless-steel cubic modules clad in diamond-shaped mirrors. The structure uses steel and wood to create gaps revealing internal triangular reflections. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/15-06_OE_LessEgoWall_04.jpg Less Ego Wall, 2015 - Olafur Eliasson Less Ego Wall (2015) by Studio Olafur Eliasson is a partition of stainless-steel cubic modules clad in diamond-shaped mirrors. The structure uses steel and wood to create gaps revealing internal triangular reflections. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/15-06_OE_LessEgoWall_03.jpg Less Ego Wall, 2015 - Olafur Eliasson Less Ego Wall (2015) by Studio Olafur Eliasson is a partition of stainless-steel cubic modules clad in diamond-shaped mirrors. The structure uses steel and wood to create gaps revealing internal triangular reflections. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/15-06_OE_LessEgoWall_02.jpg Less Ego Wall, 2015 - Olafur Eliasson Less Ego Wall (2015) by Studio Olafur Eliasson is a partition of stainless-steel cubic modules clad in diamond-shaped mirrors. The structure uses steel and wood to create gaps revealing internal triangular reflections. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/you-and-i-wandering-on-the-snakes-tail-2016-thilo-frank-x-phillip-c-reiner/ 2026-03-25T08:54:48+01:00 https://protoctrl.com/wp-content/uploads/2026/03/15-02_TF_YouAndI_01.jpg You and I wandering on the snake's tail, 2016 - Thilo Frank x Phillip C. Reiner "You and I wandering on the snake's tail" (2016) is a spiral structure of triangular wooden slats, stainless steel cables, galvanized steel, aluminum, and sensor-controlled lights. The work sits at ARKEN Museum, Ishøj, Denmark. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/15-02_TF_YouAndI_03.jpg You and I wandering on the snake's tail, 2016 - Thilo Frank x Phillip C. Reiner "You and I wandering on the snake's tail" (2016) is a spiral structure of triangular wooden slats, stainless steel cables, galvanized steel, aluminum, and sensor-controlled lights. The work sits at ARKEN Museum, Ishøj, Denmark. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/15-02_TF_YouAndI_02.jpg You and I wandering on the snake's tail, 2016 - Thilo Frank x Phillip C. Reiner "You and I wandering on the snake's tail" (2016) is a spiral structure of triangular wooden slats, stainless steel cables, galvanized steel, aluminum, and sensor-controlled lights. The work sits at ARKEN Museum, Ishøj, Denmark. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/levitation-2014-thilo-frank-x-phillip-c-reiner/ 2026-03-25T08:54:47+01:00 https://protoctrl.com/wp-content/uploads/2026/03/14-05_EX_Levitation_01.jpg Levitation, 2014 - Thilo Frank x Phillip C. Reiner "Levitation" (2014) by Thilo Frank and Phillip C. Reiner is a black powder-coated polyhedron suspended by steel cables. The work hangs from the ceiling in Kunstraum Dornbirn, Austria. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/14-05_EX_Levitation_02.jpg Levitation, 2014 - Thilo Frank x Phillip C. Reiner "Levitation" (2014) by Thilo Frank and Phillip C. Reiner is a black powder-coated polyhedron suspended by steel cables. The work hangs from the ceiling in Kunstraum Dornbirn, Austria. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/circumpolar-lantern-2014-thilo-frank-x-phillip-c-reiner/ 2026-03-25T08:54:47+01:00 https://protoctrl.com/wp-content/uploads/2026/03/13-09_TF_CircumpolarLantern_01.jpg Circumpolar Lantern, 2014 - Thilo Frank x Phillip C. Reiner Circumpolar Lantern (2014) by Thilo Frank and Phillip C. Reiner is a three-layered stainless steel structure with powder coating. It suspends a rotating light bulb on a cable to cast shadows. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/13-09_TF_CircumpolarLantern_03.jpg Circumpolar Lantern, 2014 - Thilo Frank x Phillip C. Reiner Circumpolar Lantern (2014) by Thilo Frank and Phillip C. Reiner is a three-layered stainless steel structure with powder coating. It suspends a rotating light bulb on a cable to cast shadows. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/13-09_TF_CircumpolarLantern_02.jpg Circumpolar Lantern, 2014 - Thilo Frank x Phillip C. Reiner Circumpolar Lantern (2014) by Thilo Frank and Phillip C. Reiner is a three-layered stainless steel structure with powder coating. It suspends a rotating light bulb on a cable to cast shadows. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/ekko-2012-thilo-frank-x-phillip-c-reiner/ 2026-03-25T08:54:46+01:00 https://protoctrl.com/wp-content/uploads/2026/03/11-09_TF_Ekko_01.jpg Ekko, 2012 - Thilo Frank x Phillip C. Reiner Ekko (2012) by Thilo Frank and Phillip C. Reiner is a site-specific installation in Hjallerup, Denmark. It uses wooden frames, speakers, and sensors to alter sound based on visitor movement. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/11-09_TF_Ekko_04.jpg Ekko, 2012 - Thilo Frank x Phillip C. Reiner Ekko (2012) by Thilo Frank and Phillip C. Reiner is a site-specific installation in Hjallerup, Denmark. It uses wooden frames, speakers, and sensors to alter sound based on visitor movement. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/11-09_TF_Ekko_02.jpg Ekko, 2012 - Thilo Frank x Phillip C. Reiner Ekko (2012) by Thilo Frank and Phillip C. Reiner is a site-specific installation in Hjallerup, Denmark. It uses wooden frames, speakers, and sensors to alter sound based on visitor movement. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/11-09_TF_Ekko_03.jpg Ekko, 2012 - Thilo Frank x Phillip C. Reiner Ekko (2012) by Thilo Frank and Phillip C. Reiner is a site-specific installation in Hjallerup, Denmark. It uses wooden frames, speakers, and sensors to alter sound based on visitor movement. https://protoctrl.com/legal/ https://protoctrl.com/portfolio/above-below-beneath-above-2014-olafur-eliasson/ 2026-03-25T08:54:45+01:00 https://protoctrl.com/wp-content/uploads/2026/03/11-03_OE_AboveBelowBeneathAbove_01.jpg Above Below Beneath Above, 2014 - Olafur Eliasson Above Below Beneath Above (2014) by Studio Olafur Eliasson is an installation of 56 steel columns, each 15 meters tall, and 16 suspended forms with purple glass cores and steel frames. It sits in the entrance of Market Street Tower, Singapore. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/11-03_OE_AboveBelowBeneathAbove_04.jpg Above Below Beneath Above, 2014 - Olafur Eliasson Above Below Beneath Above (2014) by Studio Olafur Eliasson is an installation of 56 steel columns, each 15 meters tall, and 16 suspended forms with purple glass cores and steel frames. It sits in the entrance of Market Street Tower, Singapore. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/11-03_OE_AboveBelowBeneathAbove_03.jpg Above Below Beneath Above, 2014 - Olafur Eliasson Above Below Beneath Above (2014) by Studio Olafur Eliasson is an installation of 56 steel columns, each 15 meters tall, and 16 suspended forms with purple glass cores and steel frames. It sits in the entrance of Market Street Tower, Singapore. https://protoctrl.com/legal/ https://protoctrl.com/wp-content/uploads/2026/03/11-03_OE_AboveBelowBeneathAbove_02.jpg Above Below Beneath Above, 2014 - Olafur Eliasson Above Below Beneath Above (2014) by Studio Olafur Eliasson is an installation of 56 steel columns, each 15 meters tall, and 16 suspended forms with purple glass cores and steel frames. It sits in the entrance of Market Street Tower, Singapore. https://protoctrl.com/legal/