What we’re doing
At AdventureTech, we are transforming industries with advanced ceramic 3D printing technology. Our focus is on innovation, custom solutions, and material development to meet the needs of industries like aerospace, healthcare, and research.
About Adventuretech: Leaders in Ceramic 3D Printing
At AdventureTech, we specialize in the development of ceramic 3D printing technology, equipment, and materials. Our team is made up of experts from top universities like Tsinghua University and the Norwegian University of Science and Technology, including professors, postdoctoral researchers, and PhDs. This expertise is what drives our innovation and makes us a leader in the field.
Our mission is to promote innovation, contribute to national development, and create value for society. We are committed to delivering complete and integrated ceramic 3D printing solutions to meet the needs of our customers, while staying true to our values of integrity and technological progress.
Founder, Ph.D.
Founder and Expert in Ceramic 3D Printing Technology with Extensive R&D Experience
Design & build completely custom layouts
Dr. Pengfei Zhu holds a Ph.D. from the University of Science and Technology of China and completed his postdoctoral research in Materials Science at Tsinghua University.
With 10 years of experience in the research and development of ceramic 3D printing technology, he is recognized as a “reserve-level” high-level talent in Shenzhen.
He has published over 10 SCI-indexed papers, applied for more than 50 patents, and been granted over 20 patents.
Dr. Zhu has led multiple research projects and played a key role in several national key R&D programs.
In recent years, the total contract value of the vertical projects he has led has exceeded 5 million RMB.
SCI
- 1
Mou, Z. , Zhong, J. , Wang, F. , Alhotan, A. , Zhu, P. , & Li, P. , et al. (2024). Zirconia crowns manufactured using digital light processing: effects of build angle and layer thickness on the accuracy. Journal of Dentistry, 151.
- 2
Song, Suocheng , et al. “PMMA light channels facilitate the additive manufacturing of complex-structured SiC reflector mirrors.” Journal of the European Ceramic Society 45.2(2025).
- 3
Wang, F. , Liu, C. , Yang, H. , Wang, H. , Zhang, H. , & Zeng, X. , et al. (2023). 4d printing of ceramic structures. Additive Manufacturing, 63.
- 4
PF.Zhu, W. Yang, R. Wang, S. Gao, B. Li, Q. Li. 2017. Direct Writing of Flexible Barium Titanate/Polydimethylsiloxane 3D Photonic Crystals with Mechanically Tunable Terahertz Properties. Adv Opt Mater.
- 5
PF. Zhu, W. Yang, R. Wang, S. Gao, B. Li, Q. Li. 2017.4D Printing of Complex Structures with a Fast Response Time to Magnetic Stimulus. ACS AMI.
- 6
N Su, P. Zhu, Y Pan, et al. 3D-printing of shape-controllable thermoelectric devices with enhanced output performance[J]. Energy, 2020 195: 12.
- 7
R. Wang, P. Zhu, W. Yang, S. Gao, B. Li, Q. Li, Direct-writing of 3D periodic TiO2 bio-ceramic scaffolds with a sol-gel ink for in vitro cell growth, Materials & Design 144 (2018) 304-309
Company History
Shenzhen Adventure Tech Co., Ltd. Was Established
In 2015, Shenzhen Adventure Technology Co., Ltd. was founded as a high-tech company specializing in ceramic additive manufacturing.
Our core team consists of postdoctoral researchers from Tsinghua University and returning PhDs from the Norwegian University of Science and Technology,
focused on developing complete solutions for ceramic 3D printing—including 3D printers, materials, and sintering processes.
Standard Edition Precision Direct-Write 3D Printer
In 2018, we successfully developed the Adventure-3D-LB-Printer Standard Edition, a high-precision printer capable of printing paste-like ink materials with exceptional quality. Our proprietary ADT-Slicer 4D printing engine enables “one-stroke forming”, while integrating the CAD-4D engine for seamless conversion of CAD paths into motion codes. This advancement greatly enhances printing efficiency and convenience. We remain committed to continuous research and product optimization to maintain our position as an industry leader.
Experimental-Level DLP Ceramic 3D Printer
Successfully developed an experimental-level DLP photopolymerization ceramic 3D printer with multi-material compatibility for high-precision printing of ceramic photopolymer materials. This printer provides optimal solutions for research and laboratory applications. Featuring a “dual-cylinder-sinking-scraping” structure, it avoids the drawbacks of traditional pull structures, requiring only 80 mL of ceramic material to start printing—making it economical and efficient for researchers.
Industrial-Grade Ultra-High-Speed DLP Ceramic 3D Printer
Successfully developed a DLP peristaltic ceramic 3D printer that employs a peristaltic feeding structure, accommodating high-viscosity and high-solid-content ceramic slurries while featuring an automatic filtration function to ensure print stability. This industrial-grade equipment is suitable for industrial applications in ceramic 3D printing, supporting mature materials such as zirconia and alumina, with a printing speed of up to 600 layers per hour. It can replace traditional injection and molding processes, shortening product validation cycles and improving production efficiency. We offer comprehensive solutions for the ceramic industry, including high-quality materials, advanced equipment, and complete sintering process technologies.
DLP Desktop Peristaltic Ceramic 3D Printer
Developed the desktop ceramic printing device ADT-3D-ZM-Ceramic-Printer, designed for laboratory use. Utilizing upright DLP projection technology, it achieves a printing efficiency of 700 layers per hour (using alumina), ranking highly worldwide. The device integrates technologies independently developed by Qiyu Technology. It features a dual-scraper structure that efficiently manages material application and recovery, ensuring even distribution of slurries with varying viscosities while preventing issues like material shortages during printing. Additionally, the filtration system combined with the peristaltic pump reduces sedimentation of ceramic slurries while filtering out residues, making it widely applicable in medical, aerospace, and environmental protection fields.
