Felipe Cerdas
Felipe Cerdas
Verified email at - Homepage
Cited by
Cited by
Life cycle assessment of 3D printed products in a distributed manufacturing system
F Cerdas, M Juraschek, S Thiede, C Herrmann
Journal of Industrial Ecology 21 (S1), S80-S93, 2017
Collaboration platform for enabling industrial symbiosis: application of the by-product exchange network model
B Raabe, JSC Low, M Juraschek, C Herrmann, TB Tjandra, YT Ng, ...
Procedia Cirp 61, 263-268, 2017
Exploring the effect of increased energy density on the environmental impacts of traction batteries: A comparison of energy optimized lithium-ion and lithium-sulfur batteries …
F Cerdas, P Titscher, N Bognar, R Schmuch, M Winter, A Kwade, ...
Energies 11 (1), 150, 2018
A big data analytics approach to develop industrial symbioses in large cities
S Bin, Y Zhiquan, LSC Jonathan, DK Jiewei, D Kurle, F Cerdas, ...
Procedia CIRP 29, 450-455, 2015
Life cycle assessment of a disposable and a reusable surgery instrument set for spinal fusion surgeries
A Leiden, F Cerdas, D Noriega, J Beyerlein, C Herrmann
Resources, Conservation and Recycling 156, 104704, 2020
Defining circulation factories–a pathway towards factories of the future
F Cerdas, D Kurle, S Andrew, S Thiede, C Herrmann, Y Zhiquan, ...
Procedia CIRP 29, 627-632, 2015
Simulation-based assessment of the energy demand in battery cell manufacturing
M Thomitzek, N Von Drachenfels, F Cerdas, C Herrmann, S Thiede
Procedia Cirp 80, 126-131, 2019
Integrated computational life cycle engineering—application to the case of electric vehicles
F Cerdas, S Thiede, C Herrmann
CIRP Annals 67 (1), 25-28, 2018
Shop-floor life cycle assessment
F Cerdas, S Thiede, M Juraschek, A Turetskyy, C Herrmann
Procedia CIRP 61, 393-398, 2017
LCE and Electromobility
F Cerdas
Integrated Computational Life Cycle Engineering for Traction Batteries, 11-55, 2022
Improved visualization in LCA through the application of cluster heat maps
F Cerdas, A Kaluza, S Erkisi-Arici, S Böhme, C Herrmann
Procedia CIRP 61, 732-737, 2017
Environmental aspects of the recycling of lithium-ion traction batteries
F Cerdas, S Andrew, S Thiede, C Herrmann
Recycling of Lithium-Ion Batteries, 267-288, 2018
Sustainability assessment and engineering of emerging aircraft technologies—Challenges, methods and tools
S Pinheiro Melo, A Barke, F Cerdas, C Thies, M Mennenga, TS Spengler, ...
Sustainability 12 (14), 5663, 2020
Disassembly planning and assessment of automation potentials for lithium-ion batteries
F Cerdas, R Gerbers, S Andrew, J Schmitt, F Dietrich, S Thiede, K Dröder, ...
Recycling of Lithium-Ion Batteries, 83-97, 2018
Exploring the opportunities of system of systems engineering to complement sustainable manufacturing and life cycle engineering
M Mennenga, F Cerdas, S Thiede, C Herrmann
Procedia CIRP 80, 637-642, 2019
Exploring the potentials of mixed reality for life cycle engineering
M Juraschek, L Büth, F Cerdas, A Kaluza, S Thiede, C Herrmann
Procedia CIRP 69, 638-643, 2018
Experiencing closed loop manufacturing in a learning environment
M Juraschek, F Cerdas, G Posselt, C Herrmann
Procedia Manufacturing 9, 57-64, 2017
Cradle-to-gate analysis of the embodied energy in lithium ion batteries
M Thomitzek, F Cerdas, S Thiede, C Herrmann
Procedia CIRP 80, 304-309, 2019
Life cycle assessment of an automotive factory: Identifying challenges for the decarbonization of automotive production–A case study
M Gebler, JF Cerdas, S Thiede, C Herrmann
Journal of cleaner production 270, 122330, 2020
Life cycle engineering based on visual analytics
A Kaluza, S Gellrich, F Cerdas, S Thiede, C Herrmann
Procedia CIRP 69, 37-42, 2018
The system can't perform the operation now. Try again later.
Articles 1–20