fekt-scara/tex/literatura.bib

% cSpell:disable

@book{2016Rarv,
  author    = {Zdeněk Kolíbal},
  publisher = {Vysoké učení technické v Brně - nakladatelství VUTIUM},
  isbn      = {978-80-214-4828-5},
  year      = {2016},
  title     = {Roboty a robotizované výrobní technologie},
  edition   = {První vydání.},
  address   = {Brno},
  keywords  = {robotika vt; průmyslové roboty a manipulátory sr; roboty; automatizované výrobní systémy; pohybové jednotky; průmyslové roboty; robotické systémy; výrobní technologie; jednoúčelové manipulátory; průmyslové balancéry}
}

@misc{FreeCAD_wiki,
  author = {{The FreeCAD Team}},
  title  = {About FreeCAD – FreeCAD Documentation},
  year   = {2013},
  update = {2019-12-06},
  annote = {[online]},
  url    = {https://wiki.freeecad.org/About_FreeCAD}
}

@misc{freecad,
  author = {{The FreeCAD Team}},
  howpublished = {software},
  title = {FreeCAD},
  year = {2002},
  note   = {[cit. 2025-1-6]}
}

@misc{x-scara,
  url    = {https://github.com/madl3x/x-scara},
  author = {Alex Mircescu},
  title  = {x-scara},
  year   = {2020},
  annote = {[online]},
  note   = {[cit. 2025-1-5]}
}

@misc{klipper_code_overview,
  title  = {Klipper Code Overview},
  author = {{Klipper 3D}},
  year   = {2023},
  url    = {https://www.klipper3d.org/Code_Overview.html},
  annote = {[online]},
  note   = {[cit. 2025-1-5]}
}

@article{GAO201565,
  title    = {The status, challenges, and future of additive manufacturing in engineering},
  journal  = {Computer-Aided Design},
  volume   = {69},
  pages    = {65-89},
  year     = {2015},
  issn     = {0010-4485},
  doi      = {https://doi.org/10.1016/j.cad.2015.04.001},
  url      = {https://www.sciencedirect.com/science/article/pii/S0010448515000469},
  author   = {Wei Gao and Yunbo Zhang and Devarajan Ramanujan and Karthik Ramani and Yong Chen and Christopher B. Williams and Charlie C.L. Wang and Yung C. Shin and Song Zhang and Pablo D. Zavattieri},
  keywords = {Additive manufacturing, 3D printing, Maker Movement, Topology optimization, Open-source machine, Intellectual property},
  abstract = {Additive manufacturing (AM) is poised to bring about a revolution in the way products are designed, manufactured, and distributed to end users. This technology has gained significant academic as well as industry interest due to its ability to create complex geometries with customizable material properties. AM has also inspired the development of the maker movement by democratizing design and manufacturing. Due to the rapid proliferation of a wide variety of technologies associated with AM, there is a lack of a comprehensive set of design principles, manufacturing guidelines, and standardization of best practices. These challenges are compounded by the fact that advancements in multiple technologies (for example materials processing, topology optimization) generate a “positive feedback loop” effect in advancing AM. In order to advance research interest and investment in AM technologies, some fundamental questions and trends about the dependencies existing in these avenues need highlighting. The goal of our review paper is to organize this body of knowledge surrounding AM, and present current barriers, findings, and future trends significantly to the researchers. We also discuss fundamental attributes of AM processes, evolution of the AM industry, and the affordances enabled by the emergence of AM in a variety of areas such as geometry processing, material design, and education. We conclude our paper by pointing out future directions such as the “print-it-all” paradigm, that have the potential to re-imagine current research and spawn completely new avenues for exploration.}
}

@misc{mcae_fff,
  author  = {{MCAE Systems}},
  title   = {FFF - Technologie aditivní výroby},
  annote  = {[online]},
  url     = {https://www.mcae.cz/technologie/fff/},
  urldate = {2025-01-05},
  note    = {[cit. 2025-1-5]}
}

@misc{wikimedia_3d_printing_calibration,
  title  = {3D printing calibration part-cooling fan airflow},
  author = {{Wikimedia Commons}},
  year   = {2019},
  url    = {https://commons.wikimedia.org/wiki/File:3D_printing_calibration_part-cooling_fan_airflow.svg},
  note   = {[cit. 2025-1-5]}
}

@article{Choudhary_Analysis,
  title    = {Analysis and optimization of geometry of 3D printer part cooling fan duct},
  journal  = {Materials Today: Proceedings},
  volume   = {50},
  pages    = {2482-2487},
  year     = {2022},
  note     = {2nd International Conference on Functional Material, Manufacturing and Performances (ICFMMP-2021)},
  issn     = {2214-7853},
  doi      = {https://doi.org/10.1016/j.matpr.2021.10.444},
  url      = {https://www.sciencedirect.com/science/article/pii/S2214785321069534},
  author   = {Mantu Choudhary and Sumanta Mukherjee and Prakash Kumar},
  keywords = {3D printer, Part cooling fan, Cooling fan duct, Convergent-divergent},
  abstract = {Part cooling fans are used in FDM 3D printers to control the deposition quality and warping issues. However, the fan ducts used for the purpose are often non-optimized, and therefore, the performance of such ducts can be improved by analyzing the geometry and adopting necessary modifications. This work looks into the geometry of the part cooling fan duct of a common commercial 3D printer, and studies the influence of a convergent-divergent type duct opening on the flow behavior. The inlet and outlet angles and the throat length have been analyzed numerically to identify the most suitable geometry. Results indicate that there are optimum values for all of these three geometrical parameters to obtain the highest air flow velocity at the outlet, and the flow behavior deteriorates beyond such optimum parameters. From the numerical analysis, the optimized convergent-divergent duct having 20° outlet angle, 3 mm throat length, and 40° inlet angle can increase the average air flow velocity by approximately 23% over the air flow velocity of a standard part cooling fan without the convergent- divergent section.}
}

@book{Prusa_Zaklady_3D_tisku,
  author    = {Ondřej Stříteský},
  title     = {Základy 3D tisku s Josefem Průšou},
  publisher = {Prusa Research},
  year      = {2019},
  address   = {Praha},
  keywords  = {3D tisk; FDM; SLA; SLS; SLM; DLP; technologie; materiály; software; hardware}
}

@misc{materialpro3d_typy_povrchu,
  author  = {{Materialpro3D}},
  title   = {Typy povrchů tiskové podložky},
  year    = {2021},
  url     = {https://www.materialpro3d.cz/blog/typy-povrchu-tiskove-podlozky/},
  urldate = {2025-01-05},
  note    = {[cit. 2025-1-5]}
}

@misc{dangerklipper_resonance_compensation,
  author = {{Danger Klipper}},
  title  = {Kompenzace rezonance},
  url    = {https://dangerklipper.io/Resonance_Compensation.html},
  note   = {[cit. 2025-1-5]}
}

@misc{corexz_theory,
  author = {{ALEDAN 3D Research Lab}},
  title  = {CoreXZ -- Theory},
  year   = {2018},
  annote = {[online]},
  url    = {https://www.corexz.com/theory.html},
  note   = {[cit. 2025-1-5]}
}

@misc{all3dp_3d_printer_types,
  author = {Jackson O'Connell},
  title  = {Cartesian, Delta, Polar, and More: Types of 3D Printer Mechanics},
  year   = {2023},
  annote = {[online]},
  url    = {https://all3dp.com/2/cartesian-3d-printer-delta-scara-belt-corexy-polar/},
  note   = {[cit. 2025-1-5]}
}

@misc{thingiverse_3dbuider_delta_xxl,
  author = {{3DsvetEU}},
  title  = {3DBuilder DELTA XXL 3D printer by 3Dsvet.eu},
  year   = {2017},
  annote = {[online]},
  url    = {https://www.thingiverse.com/thing:2571355},
  note   = {[cit. 2025-1-5]}
}

@misc{guicol_polar_printer_concept,
  author = {{guicol}},
  title  = {Received a ton of constructive criticism on my crude polar-3D Printer design. Redesigned it with improvements.},
  annote = {[online]},
  year   = {2023},
  note   = {[cit. 2025-1-4]},
  url    = {https://www.reddit.com/r/3Dprinting/comments/16dsugh/received_a_ton_of_constructive_criticism_on_my/}
}

@misc{all3dp_direct_vs_bowden,
  author = {Tobias Hullette},
  title  = {Direct Drive vs Bowden Extruder: The Differences},
  year   = {2024},
  annote = {[online]},
  url    = {https://all3dp.com/2/direct-vs-bowden-extruder-technology-shootout/},
  note   = {[cit. 2025-1-6]}
}

@misc{madl3x_scara_image,
  author   = {Alex Mircescu},
  title    = {XSCARA V1 - Complete Assembly STEP files},
  year     = {2021},
  annotate = {[online]},
  url      = {https://cults3d.com/en/3d-model/various/xscara-v1-complete-assembly-step-files},
  note     = {[cit. 2025-1-6]}
}

@misc{reprap_morgan,
  author   = {Quentin Harley},
  title    = {RepRap Morgan},
  year     = {2016},
  annotate = {[online]},
  url      = {https://reprap.org/wiki/RepRap_Morgan},
  note     = {[cit. 2025-1-6]}
}

@misc{prouzeau_halenia,
  author   = {Pierre Rouzeau},
  title    = {Halenia CoreXY printer},
  year     = {2016},
  annotate = {[online]},
  url      = {https://github.com/PRouzeau/Halenia-CoreXY-printer/},
  note     = {[cit. 2025-1-6]}
}

@misc{creality_cr30,
  author   = {{Creality}},
  title    = {CR-30 3D Printer},
  annotate = {[online]},
  url      = {https://www.creality.com/products/creality-cr-30-3d-printer},
  note     = {[cit. 2025-1-6]}
}

@misc{formlabs_watertight_3d_printing,
  author   = {{Formlabs}},
  title    = {Guide to Watertight 3D Printing},
  annotate = {[online]},
  url      = {https://formlabs.com/eu/blog/watertight-3d-printing/},
  note     = {[cit. 2025-1-4]}
}

@article{app14020945,
  author         = {Kaščak, Jakub and Kočiško, Marek and Vodilka, Adrián and Török, Jozef and Coranič, Tomáš},
  title          = {Adhesion Testing Device for 3D Printed Objects on Diverse Printing Bed Materials: Design and Evaluation},
  journal        = {Applied Sciences},
  volume         = {14},
  year           = {2024},
  number         = {2},
  article-number = {945},
  url            = {https://www.mdpi.com/2076-3417/14/2/945},
  issn           = {2076-3417},
  abstract       = {The persistent challenge of adhesion in Fused Filament Fabrication (FFF) technology is deeply rooted in the mechanical and chemical properties of utilized materials, necessitating the exploration of potential resolutions. This involves adjustments targeting the interplay of printing parameters, the mechanical fortification of print beds, and the integration of more adhesive materials, resonating across user levels, from enthusiasts to complex industrial configurations. An in-depth investigation is outlined in this paper, detailing the plan for a systematically designed device. Engineered for FFF device installation, the device facilitates the detachment of printed models, while precisely recording the detachment process, capturing the maximum force, and its progression over time. The primary objective is fabricating a comprehensive measurement apparatus, created for adhesion assessment. The device is adaptable across diverse FFF machines and print bed typologies, conforming to pre-defined conditions, with key features including compactness, facile manipulability, and capacity for recurrent measurements. This pursuit involves evaluating adhesion levels in prints made from diverse materials on varying print bed compositions, aiming to establish a comprehensive database. This repository facilitates judicious material and bed type selection, emphasizing maximal compatibility. Emphasis is placed on operating within a thermally stable context, a pivotal prerequisite for consistent and reproducible results.},
  doi            = {10.3390/app14020945}
}