Details
3D Paper Printing for the Built Environment
Optimization of the Material Behavior & Production Process to Reach Quality Integration and Dimensional AccuracyMechanik, Werkstoffe und Konstruktion im Bauwesen, Band 73
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CHF 236.00 |
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| Verlag: | Springer Vieweg |
| Format: | |
| Veröffentl.: | 24.06.2024 |
| ISBN/EAN: | 9783658450762 |
| Sprache: | englisch |
| Anzahl Seiten: | 360 |
Dieses eBook enthält ein Wasserzeichen.
Beschreibungen
<p>This book presents the manufacture and development of products from a novel material formulation as a bio-based paper material using 3D printing for engineering purposes. The approach is to optimize the material behavior and the manufacturing process to achieve a high level of quality and accuracy. A wide range of formulations are investigated to select homogeneous pastes with high 3D printing potential for best outcomes. <br>
This is accomplished through customization and optimization under the control of rheological behavior and printing parameters. Mechanical characterization is investigated to identify the adhesion and other properties of the paste formulation. <br>
Potential applications for the built environment in façade construction are presented, which match the material properties and benefit the most from the complexity offered by additive manufacturing technology.</p>
<p><strong>The content</strong></p>
<ul>
<li>State of Art</li>
<li>Printing Configuration and Performance</li>
<li>Quality & Accuracy Assessment</li>
<li>Material & Mechanical Behavior</li>
<li>3D Models as a Case Study</li>
</ul>
This is accomplished through customization and optimization under the control of rheological behavior and printing parameters. Mechanical characterization is investigated to identify the adhesion and other properties of the paste formulation. <br>
Potential applications for the built environment in façade construction are presented, which match the material properties and benefit the most from the complexity offered by additive manufacturing technology.</p>
<p><strong>The content</strong></p>
<ul>
<li>State of Art</li>
<li>Printing Configuration and Performance</li>
<li>Quality & Accuracy Assessment</li>
<li>Material & Mechanical Behavior</li>
<li>3D Models as a Case Study</li>
</ul>
<p>Introduction.- State of the Art.- Printing Configuration & Performance.- Assessment of print quality.- Material & Mechanical Characteristics.- 3D Models as Cases Study.- Conclusion and Recommendation.</p>
<p><strong>Dunia Abdullah Agha</strong> holds a degree in Civil Engineering/specialization in Structural Engineering from the University of Babylon, Iraq. From 2009-2018, she worked as a projects engineer in the Governorate Office of Babylon, Iraq. From 2018-2023, she worked as a research assistant and lecturer at the Institute of Structural Analysis and Design at the Technical University of Darmstadt, Germany, with a grant from the German Academic Exchange Service (DAAD). Since 2024, she works as a projects engineer/structural designer at Krebs und Kiefer Ingenieure GmbH/Darmstadt.</p>
<p>This book presents the manufacture and development of products from a novel material formulation as a bio-based paper material using 3D printing for engineering purposes. The approach is to optimize the material behavior and the manufacturing process to achieve a high level of quality and accuracy. A wide range of formulations are investigated to select homogeneous pastes with high 3D printing potential for best outcomes. <br>
This is accomplished through customization and optimization under the control of rheological behavior and printing parameters. Mechanical characterization is investigated to identify the adhesion and other properties of the paste formulation. <br>
Potential applications for the built environment in façade construction are presented, which match the material properties and benefit the most from the complexity offered by additive manufacturing technology.</p>
<p><strong>The content</strong></p>
<ul>
<li>State of Art</li>
<li>Printing Configuration and Performance</li>
<li>Quality & Accuracy Assessment</li>
<li>Material & Mechanical Behavior</li>
<li>3D Models as a Case Study</li>
</ul>
<p><strong>The author</strong><br>
<strong>Dunia Abdullah Agha</strong> holds a degree in Civil Engineering/specialization in Structural Engineering from the University of Babylon, Iraq. From 2009-2018, she worked as a projects engineer in the Governorate Office of Babylon, Iraq. From 2018-2023, she worked as a research assistant and lecturer at the Institute of Structural Analysis and Design at the Technical University of Darmstadt, Germany, with a grant from the German Academic Exchange Service (DAAD). Since 2024, she works as a projects engineer/structural designer at Krebs und Kiefer Ingenieure GmbH/Darmstadt.</p>
This is accomplished through customization and optimization under the control of rheological behavior and printing parameters. Mechanical characterization is investigated to identify the adhesion and other properties of the paste formulation. <br>
Potential applications for the built environment in façade construction are presented, which match the material properties and benefit the most from the complexity offered by additive manufacturing technology.</p>
<p><strong>The content</strong></p>
<ul>
<li>State of Art</li>
<li>Printing Configuration and Performance</li>
<li>Quality & Accuracy Assessment</li>
<li>Material & Mechanical Behavior</li>
<li>3D Models as a Case Study</li>
</ul>
<p><strong>The author</strong><br>
<strong>Dunia Abdullah Agha</strong> holds a degree in Civil Engineering/specialization in Structural Engineering from the University of Babylon, Iraq. From 2009-2018, she worked as a projects engineer in the Governorate Office of Babylon, Iraq. From 2018-2023, she worked as a research assistant and lecturer at the Institute of Structural Analysis and Design at the Technical University of Darmstadt, Germany, with a grant from the German Academic Exchange Service (DAAD). Since 2024, she works as a projects engineer/structural designer at Krebs und Kiefer Ingenieure GmbH/Darmstadt.</p>
Vielseitig: 3D-gedruckte Papierprodukte bieten detaillierte Kunstwerke und funktionale Modelle mit einer Zugkraft 5 MPa Leichtgewichtig, kosteneffizient: Papier ist leichter und günstiger als andere Materialien Ökologisch: 3D-Papierprodukte sind recycelbar und die Nutzung von Recyclingpapier als Hauptmaterial spart Ressourcen
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