인스타그램 스토리 뷰어
인스타그램 스토리를 익명으로 보기
hyper.press
hyperpress
ontology of print
3D printing & graphic design
#3Dprintedbooks
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
Excited to have SLIC3D, my first 3D printed book acquired by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
—
SLIC3D
Dating: 2021-22
Dimensions: 20.5 x 15.5 x 1.0 cm
Medium/material: 3D printed Thermoplastic polyurethane (pages), polylactic acid (spine)
Edition: Unique
Photography: @ve.you.vu
Photogrammetry: @jonathantyl
#graphicdesign #3dprintedbooks #3dprintedbook
CORPOREAL will accompany CORPUS's acquisition by Singapore Art Museum @singaporeartmuseum into the permanent Design Collection.
---
CORPOREAL
Dating: 2024
Dimension: 4 minutes 12 seconds
Medium / Materials: Single channel 4K video
Edition: 1 (1+AP)
Special thanks to @gideon_kong
Photography by @j__neo and Chan Jian Hong
#graphicdesign #3dprintedbooks #3dprintedbook
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
Happy to announce that CORPUS, my second 3D printed book has been acquired by Singapore Art Museum @singaporeartmuseum and will enter the permanent Design Collection.
---
CORPUS
Dating: 2022-23
Dimension: 17.0 x 10.5 x 2.5 cm
Medium / Materials: 3D printed/Thermoplastic polyurethane
Edition: Unique
Gaussian splatting/Photogrammetry with @jonathantyl
#graphicdesign #3dprintedbooks #3dprinting
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
building an archive, an inventory, a numbered list, a taxonomy, a glossary, a lexicon, a lore, a vector, a hypothesis, a research, and a practice for 3D printed books.
hyperpre.ss (link in bio)
beta site
Initiated in 2021, hyperpress is a programme of research spanning 3D printing, graphic design, and publishing—producing 3D printed books, objects, and texts. The research traces the ontology of print by situating additive manufacturing within the lineage of the printing press, where 3D printed books materialise a counterfactual trajectory.
#3dprintedbooks #graphicdesign
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
FINAL RESEARCH presents SESSION, an initiative with the goal of creating a space for global design discourse through live lecture, platforming people and practices that critically engage with design and research. SESSION is hosted at New Stadium @newsystems_ in Toronto with our guest speakers joining us virtually.
[INFORMATION]
Our first guest is Darius Ou @darius_ou , a Singapore-based graphic designer whose practice focuses on typography, motion design and graphic lore. He runs hyperpress @hyper.press , a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts. He is a recipient of the ADC New York Young Guns 21 award, and the Tokyo Type Directors Club Annual Award 2026.
[DATE]
Wed 04.29.2026
[LOGISTICS]
Darius will be giving a 75 minute talk followed by an extended Q&A period with time for social after.
Doors open at 7PM with talks beginning at 7:45. Guests are welcome to bring beverages. Snacks and non-alcoholic drinks will be provided.
[RSVP]
Seats are limited. Follow the link in bio to RSVP and guarantee entry. This event is PWYC, a $5 donation is suggested to cover costs and labour.
FR_12_P
TALK
LUMA.COM/DARIUSOU
#DARIUSOU
#FINALRESEARCH
#NEW
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
A slice of METALLY is now exhibiting at the @ginzagraphicgallery (ggg) as a Selected Work for @tokyotdc Tokyo Type Director's Club Awards 2026. This exhibited slice is a reworked prototype page from the development process and represents METALLY (2025) at the space.
Also shown in this post are additional images of the inner workings and circuitry of the book from development. This 3D printed book took approximately 6 months of conceptualisation, hardware and software tests, and production of the proof-of-concept object. More at @hyper.press
—
Check out all 124 winning works at the TDC Tokyo Exhibition
Dates: April 03, 2026 – May 16, 2026
Closed on Sundays and holidays (April 29, May 4-6)
Venue: Ginza Graphic Gallery (ggg)
Hours: 11:00-19:00
Address: DNP Ginza Bldg. 1F/B1F, 7-7-2 Ginza, Chuo-ku, Tokyo
#3dprintedbooks
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
METALLY (2025) has been selected for the Tokyo Type Directors Club Annual Award 2026 @tokyotdc as Excellent Work for the Experimental Work Category.
This marks an important milestone for the development of 3D printed books and re-emphasises their lineage in the printing press and tradition of graphic design. Beyond destabilising the ontology of print, 3D printed books interrogate the production processes and workflows of book-objects by retracing historical practices while speculating on their future.
METALLY is a culmination of various experimental processes developed over years from previous titles (and from countless failures), such as flexible 3D printed substrates, purpose-built typeface and methodology for 3D printing (termed path-trapping), Multi-material mechanical interlocking for printing images (termed clotting) and other methods documented at @hyper.press.
Special thanks to @feelers_feelers @joandkapi for the support,
@hiddnur, @sojamo, @msjospark, Dr Aprille, for the invaluable guidance.
Photography @jonathantyl Talent @suvalidh
#3dprintedbooks #graphicdesign
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
Prototype book-objects
These book-objects are 3D printed upright, from spine to fore-edge. Every piece is littered with randomly generated artefacts produced by the printer's pathing system, exploring accidental mark-making through the machines's vibration, belt patten ringing, and pathing mechanics. Through randomised start and end points per layer, each book-object is printed with a unique path. These artefacts are often perceived as printing flaws—here they are part of @hyper.press machine's unique signature through specific software settings and hardware intricacies.
The logomark on the cover is made using a "x-for-z" method, where relief marks are printed through movements on the x-axis rather than z-axis—a maneuver only possible through 3D printing the book-object upright instead of cover-flat on surface.
These exercises serves as a proof-of-concept for a process for 3D printing a book all at once. Each piece is produced from the same filament spool that was used to produce previous @hyper.press titles. Available @labour_block . While spool lasts.
Limited drop @labour_block
LABOUR BLOCK Mini Docs
Chapter 2: @hyper.press @darius_ou
hyperpress is a research initiative and body of work exploring the intersections of 3D printing, graphic design and publishing—producing 3D printed books, objects and texts.
Edit: JX Soo (@jadeexcess)
Shot by: JX Soo + Justin Tan (@just.a.tin)
--
OPEN STUDIO EVENT & MARKETPLACE
24—25 JAN, 1PM—8PM
*SCAPE GROUND THEATRE (@scapesg)
MORE INFO >>> LINK IN BIO
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
DOUBLE SLIT EXPERIMENTS
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 feature a double-slit joint system across its constellation of spines. Conceived by polymath Thomas Young, the double-slit experiments from 1801 have since been explored in many branches in physics, including quantum mechanics. Initially designed to demonstrate the dual wave–particle behaviour of light and matter, the experiment later gave rise to profound scientific and philosophical questions concerning measurement, observation, and consciousness itself. The primary consequences of the findings from these experiments stem from how classical particles can exhibit behaviours of waves only under unobserved circumstances, either mechanically or by human interactions.
𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴’s binding mechanism draws simultaneously on the technical logic of the double-slit apparatus and on the conceptual perplexities it exposes—the dualities that emerge from interactions. Each spread of 𝘔𝘢𝘯𝘺-𝘧𝘰𝘭𝘥𝘴 is 3D-printed with a pair of slits at the centrefold and extended tabs along the fore edges. These tabs are designed to be threaded through the centrefold slits of adjacent spreads and heat-bound together, forming a continuous, branching system of spreads.
Book prose by @daisyfay
#3dprintedbooks #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴
2025
1500mm x 1000mm (without spool)
Medium: 3D printed book, Thermoplastic polyurethane
Commissioned by ArtScience Museum Singapore
Book prose by Samantha Yap @daisyfay
#3dprintedbook #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
MANY FOLDS OF THE SURFACE
The cover of 𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 features an experimental technique developed at @hyper.press for spot iridescent 3D printed graphics on 3D printed books. Building on a diffraction-grating transfer technique developed within the larger 3D printing community, a multi-material workflow was devised to enable selective grating transfer across specific regions of the print surface.
A diffraction grating operates through micro-periodic patterns etched onto material—like a surface folded over and over—causing incoming light waves to diffract and interfere with one another, thereby generating a spectrum. By 3D printing directly over a diffraction grating surface, the microstructures can be imprinted onto the bed-facing surface of the 3D printed object, which transfers the optical phenomenon to the print.
Conceptually it is important to think about this process as transfer of phenomenon, not ink. Conventional printing involves the transfer of ink onto a substrate, whereas this is an imprinting of pronounced, three-dimensional structures from surface to surface, resulting in transfer of optical phenomenon.
With progress from FFF 3D printing technologies, 3D printers might benefit from development in deposition resolution to be able to fabricate the diffraction microstrucutures natively in the future.
Book prose by @daisyfay
𝘔𝘢𝘯𝘺-𝘍𝘰𝘭𝘥𝘴 is commissioned by and exhibited at ArtScience Museum till 22 Feb 2026. Special thanks to Joshua, Joel, Charleen and the exhibition team.
#3Dprintedbooks #graphicdesign
비밀리에 인스타그램 스토리 보기
인스타그램 스토리 뷰어는 인스타그램 스토리, 비디오, 사진 또는 IGTV를 비밀리에 보고 저장할 수 있는 간단한 도구입니다. 이 서비스를 통해 콘텐츠를 다운로드하고 언제든지 오프라인으로 즐길 수 있습니다. 인스타그램에서 나중에 확인하고 싶은 흥미로운 콘텐츠를 찾거나 익명으로 스토리를 보고 싶다면, 우리 뷰어가 적합합니다. Anonstories는 신원을 숨길 수 있는 훌륭한 솔루션을 제공합니다. 인스타그램은 2023년 8월에 스토리 기능을 출시했으며, 이 기능은 흥미롭고 시간에 민감한 형식으로 빠르게 다른 플랫폼에 채택되었습니다. 스토리는 사용자가 텍스트, 이모지 또는 필터로 보강된 사진, 비디오 또는 셀카를 공유할 수 있게 해주며, 24시간 동안만 표시됩니다. 이 제한된 시간 동안 높은 참여를 유도하며 일반 게시물보다 더 많은 반응을 얻을 수 있습니다. 오늘날 스토리는 소셜 미디어에서 연결하고 소통하는 가장 인기 있는 방법 중 하나입니다. 그러나 스토리를 볼 때, 제작자는 자신의 뷰어 목록에서 당신의 이름을 볼 수 있으며, 이는 개인 정보 보호에 대한 우려를 일으킬 수 있습니다. 만약 스토리를 아무도 모르게 탐색하고 싶다면? 그때 Anonstories가 유용해집니다. 이 도구는 신원을 드러내지 않고 공개된 인스타그램 콘텐츠를 볼 수 있게 해줍니다. 관심 있는 프로필의 사용자명을 입력하면 해당 프로필의 최신 스토리를 확인할 수 있습니다. Anonstories 뷰어의 특징: - 익명 브라우징: 뷰어 목록에 나타나지 않고 스토리를 볼 수 있습니다. - 계정 필요 없음: 인스타그램 계정에 가입하지 않고 공개 콘텐츠를 볼 수 있습니다. - 콘텐츠 다운로드: 스토리 콘텐츠를 직접 다운로드하여 오프라인에서 사용할 수 있습니다. - 하이라이트 보기: 24시간 제한을 넘어서 인스타그램 하이라이트를 볼 수 있습니다. - 리포스트 모니터링: 개인 프로필의 스토리 리포스트나 참여도를 추적할 수 있습니다. 제한 사항: - 이 도구는 공개 계정에서만 작동하며, 개인 계정은 접근할 수 없습니다. 장점: - 개인 정보 보호 친화적: 인스타그램 콘텐츠를 보면서도 눈에 띄지 않습니다. - 간단하고 쉬움: 앱 설치나 등록이 필요 없습니다. - 독점 도구: 인스타그램에서 제공하지 않는 방식으로 콘텐츠를 다운로드하고 관리할 수 있습니다.
Anonstories의 장점
인스타그램 스토리 비공개로 탐색
인스타그램 업데이트를 비밀리에 추적하고 개인 정보를 보호하며 익명으로 남을 수 있습니다.
개인 인스타그램 뷰어
개인 프로필 뷰어를 사용하여 쉽게 프로필과 사진을 익명으로 볼 수 있습니다.
무료 스토리 뷰어
이 무료 도구는 인스타그램 스토리를 익명으로 볼 수 있게 해주며, 스토리 업로더에게 활동을 숨길 수 있습니다.
자주 묻는 질문
익명성
Anonstories는 사용자가 인스타그램 스토리를 볼 때 제작자에게 알림을 보내지 않도록 합니다.
디바이스 호환성
iOS, Android, Windows, macOS, Chrome, Safari와 같은 최신 브라우저에서 원활하게 작동합니다.
안전성 및 개인 정보 보호
로그인 정보 없이 안전하고 익명으로 브라우징할 수 있습니다.
등록 필요 없음
사용자는 간단히 사용자명을 입력하여 공개된 스토리를 볼 수 있습니다. 계정이 필요하지 않습니다.
지원 형식
사진(JPEG)과 비디오(MP4)를 쉽게 다운로드합니다.
비용
이 서비스는 무료로 제공됩니다.
비공개 계정
비공개 계정의 콘텐츠는 팔로워만 접근할 수 있습니다.
파일 사용
파일은 개인적 또는 교육적 용도로만 사용 가능하며 저작권 규정을 준수해야 합니다.
작동 방식
공개된 사용자명을 입력하여 스토리를 보거나 다운로드할 수 있습니다. 서비스는 콘텐츠를 로컬에 저장할 수 있는 직접 링크를 생성합니다.