A review of 3D printing techniques for environmental applications

被引:123
作者
Nadagouda, Mallikarjuna N. [1 ]
Ginn, Megan [2 ]
Rastogi, Vandita [2 ]
机构
[1] US EPA, Ctr Environm Solut & Emergency Response, Chem Methods & Treatments Branch, Water Infrastruct Div, 26 West Martin Luther King Dr, Cincinnati, OH 45268 USA
[2] Univ Cincinnati, Dept Chem & Environm Engn, Cincinnati, OH 45221 USA
来源
CURRENT OPINION IN CHEMICAL ENGINEERING | 2020年 / 28卷
关键词
SUSTAINABILITY;
D O I
10.1016/j.coche.2020.08.002
中图分类号
Q81 [生物工程学(生物技术)]; Q93 [微生物学];
学科分类号
071005 ; 0836 ; 090102 ; 100705 ;
摘要
With a wide variety of techniques and compatible materials, three-dimensional (3D) printing is becoming increasingly useful in environmental applications in air, water, and energy. Through the advantages of quick production, cost-effectiveness, customizable design, the ability to produce complex geometries, and more, 3D printing has supported improvements to air quality monitors, filters, membranes, separation devices for water treatment, microbial fuel cells, solar cells, and wind turbines. It also supports sustainable manufacturing through reduced material waste, energy use, and carbon emissions. Applications of 3D printing within four environmental disciplines are described in this article: sustainable manufacturing, air quality, water and wastewater, and alternative energy sources.
引用
收藏
页码:173 / 178
页数:6
相关论文
共 35 条
[1]   Laser metal deposition technique: sustainability and environmental impact [J].
Abdulrahman, Kamardeen O. ;
Akinlabi, Esther T. ;
Mahamood, Rasheedat M. .
15TH GLOBAL CONFERENCE ON SUSTAINABLE MANUFACTURING, 2018, 21 :109-116
[2]   3D-printed clay-based ceramic water filters for point-of-use water treatment applications [J].
Akowanou, Akuemaho Virgile Onesime ;
Deguenon, Hontonho Esperance Justine ;
Groendijk, Leo ;
Aina, Martin Pepin ;
Yao, Benjamin Kouassi ;
Drogui, Patrick .
PROGRESS IN ADDITIVE MANUFACTURING, 2019, 4 (03) :315-321
[3]   Magnetically navigable 3D printed multifunctional microdevices for environmental applications [J].
Bernasconi, Roberto ;
Carrara, Elena ;
Hoop, Marcus ;
Mushtaq, Fajer ;
Chen, Xiangzhong ;
Nelson, Bradley J. ;
Pane, Salvador ;
Credi, Caterina ;
Levi, Marinella ;
Magagnin, Luca .
ADDITIVE MANUFACTURING, 2019, 28 :127-135
[4]   3D printed porous carbon anode for enhanced power generation in microbial fuel cell [J].
Bian, Bin ;
Shi, Dai ;
Cai, Xiaobing ;
Hu, Mingjun ;
Guo, Qiuquan ;
Zhang, Chuhong ;
Wang, Qi ;
Sun, Andy Xueliang ;
Yang, Jun .
NANO ENERGY, 2018, 44 :174-180
[5]   Additive Manufacturing of a Microbial Fuel Cell-A detailed study [J].
Calignano, Flaviana ;
Tommasi, Tonia ;
Manfredi, Diego ;
Chiolerio, Alessandro .
SCIENTIFIC REPORTS, 2015, 5
[6]   Emissions and health risks from the use of 3D printers in an occupational setting [J].
Chan, Felix L. ;
Hon, Chun-Yip ;
Tarlo, Susan M. ;
Rajaram, Nikhil ;
House, Ronald .
JOURNAL OF TOXICOLOGY AND ENVIRONMENTAL HEALTH-PART A-CURRENT ISSUES, 2020, 83 (07) :279-287
[7]   3D-printed ceramic structures with in situ grown whiskers for effective oil/water separation [J].
Chen, Zhe ;
Zhang, Danwei ;
Peng, Erwin ;
Ding, Jun .
CHEMICAL ENGINEERING JOURNAL, 2019, 373 :1223-1232
[8]  
Davis MS, 2018, INT RENEW SUST ENERG, P410
[9]   Assessment of 3D printing using fused deposition modeling and selective laser sintering for a circular economy [J].
DePalma, K. ;
Walluk, M. R. ;
Murtaugh, A. ;
Hilton, J. ;
McConky, S. ;
Hilton, B. .
JOURNAL OF CLEANER PRODUCTION, 2020, 264
[10]   A comprehensive review of recent developments in 3D printing technique for ceramic membrane fabrication for water purification [J].
Dommati, Hitesh ;
Ray, Saikat Sinha ;
Wang, Jia-Chang ;
Chen, Shiao-Shing .
RSC ADVANCES, 2019, 9 (29) :16869-16883
1234