Optimizing 3D-printed, reusable metal n95 filters by 3D characterization and modeling

被引：0

作者：

Acierno, Aaron ^{[1
]}

Stevens, Erica ^{[1
]}

Sedlar, Teddi ^{[1
]}

Kimes, Katerina ^{[1
]}

Chmielus, Markus ^{[1
]}

Svihla, Kurt ^{[2
]}

Pilz, Steve ^{[2
]}

Dougherty, Patrick ^{[3
]}

Spirka, Thomas ^{[4
]}

机构：

[1] Department of Mechanical and Materials Science Engineering, University of Pittsburgh, United States

[2] Ansys Inc, Canonsburg,PA, United States

[3] The ExOne Company, North Huntingdon,PA, United States

[4] Synopsys Inc, Mountain View,CA, United States

来源：

Advanced Materials and Processes | 2021年 / 179卷 / 02期

关键词：

D O I：

暂无

中图分类号：

TS8 [印刷工业]; TS951 [文教用品制造工业];

学科分类号：

摘要：

As N95 masks are in short supply and high demand, reusable, sterilizable metal filters for masks built using 3D microstructural characterization and simulation methods are a promising alternative. © 2021, ASM International. All rights reserved.

引用

页码：23 / 26

共 50 条

[41] Gold Nanoparticles on 3D-Printed Filters: From Waste to Catalysts [J].

Lahtinen, Elmeri ;

Kukkonen, Esa ;

Kinnunen, Virva ;

Lahtinen, Manu ;

Kinnunen, Kimmo Marko ;

Suvanto, Sari ;

Vaisanen, Ari ;

Haukka, Matti .

ACS OMEGA, 2019, 4 (16) :16891-16898

[42] Optimizing the macrostructure of 3D-printed pipe surfaces to improve cleanability [J].

Hanisch, Tobias ;

Joppa, Matthias ;

Eisenrauch, Vincent ;

Jacob, Sebastian ;

Mauermann, Marc .

HEAT AND MASS TRANSFER, 2024, 60 (05) :887-895

[43] Personalized 3D-printed frames to reduce leak from N95 filtering facepiece respirators: A prospective crossover trial in health care workers [J].

Chapman, Darius ;

Strong, Campbell ;

Ullah, Shahid ;

Richards, Lauren ;

Ganesan, Anand N. .

JOURNAL OF OCCUPATIONAL AND ENVIRONMENTAL HYGIENE, 2023, 20 (07) :304-314

[44] Optimizing the macrostructure of 3D-printed pipe surfaces to improve cleanability [J].

Tobias Hanisch ;

Matthias Joppa ;

Vincent Eisenrauch ;

Sebastian Jacob ;

Marc Mauermann .

Heat and Mass Transfer, 2024, 60 :887-895

[45] Optimizing Color-Difference Formulas for 3D-Printed Objects [J].

Huang, Min ;

Gao, Xinyuan ;

Pan, Jie ;

Li, Xiu ;

Hemingray, Caroline ;

Xiao, Kaida ;

Melgosa, Manuel .

SENSORS, 2022, 22 (22)

[46] 3D-Printed Models for Optimizing Tactile Braille & Shape Display [J].

Etezad, Maryam ;

Joshi, Rajeev ;

Alexander, Robert ;

Cibrian, Franceli L. .

IEEE TRANSACTIONS ON HAPTICS, 2024, 17 (04) :782-793

[47] A 3D-printed metal column for micro gas chromatography [J].

Phyo, Sooyeol ;

Choi, Sung ;

Jang, Jaeheok ;

Choi, Sun ;

Lee, Jiwon .

LAB ON A CHIP, 2020, 20 (18) :3435-3444

[48] 3D-printed metal electrodes for electrochemical detection of phenols [J].

Cheng, Tay Siew ;

Nasir, Muhammad Zafir Mohamad ;

Ambrosi, Adriano ;

Pumera, Martin .

APPLIED MATERIALS TODAY, 2017, 9 :212-219

[49] Peridynamic modeling of interfacial failure in 3D-printed concrete [J].

Duan, Yuhang ;

Wang, Chuan ;

Yin, Binbin ;

Liew, K. M. .

INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES, 2025, 301

[50] Modeling of the coefficient of thermal expansion of 3D-printed composites [J].

Polyzos, E. ;

Van Hemelrijck, D. ;

Pyl, L. .

INTERNATIONAL JOURNAL OF MECHANICAL SCIENCES, 2024, 268

← 1 2 3 4 5 →