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3D Concrete Printing Technology : Configuration with Green and Self-Healing Concrete.
- Format:
- Book
- Author/Creator:
- Brar, T. S.
- Kamāl, Muḥammad, author.
- Singh, Shubham, author.
- Series:
- Materials Research Foundations
- Materials Research Foundations ; v.134
- Language:
- English
- Physical Description:
- 1 online resource (95 pages)
- Edition:
- 1st ed.
- Place of Publication:
- Millersville : Materials Research Forum LLC, 2022.
- Summary:
- The book presents a detailed comparison between traditional construction techniques and 3D printing construction.
- Contents:
- Intro
- Table of Contents
- Preface
- Introduction
- 1. Introduction
- 2. Justification and Need for the Study
- 3. Objectives of the Study
- 4. Scope and Limitations
- 5. Research Methodology
- 6. The Expected Outcomes
- Conventional Construction Technology
- 2. Evolution of Construction Technology
- 3. Cast-in-Situ Construction Technology
- 3.1 Composition/Mix Design in Cast-in-Situ Construction
- 3.1.1 Cement, Sand and Coarse Aggregate Requirement for M20 Grade Concrete
- 3.1.2 Weight of Cement Required for 1 Cubic Meter of M20 Grade Concrete
- 3.1.3 Volume of Sand and Aggregate Required for 1 Cubic Meter of M20 Grade Concrete
- 3.1.4 Volume of Sand and Aggregate Required for 1 Cubic Meter of M20 Grade Concrete
- 3.2 Cost Analysis of Cast-in-Situ Construction
- 3.3 Rate Analysis for 1 cum Concrete of M20 (1:1.5:3)
- 4. Pre-Cast Construction Technology
- 4.1 Types of Precast Elements
- 4.2 Machinery Used in Pre-Cast Technology
- 4.2.1 Hollow Core Slab Production
- 4.2.2 Production of Wall, Beam and Column
- 4.2.3 Concrete Distribution
- 4.2.4 Batching Plant
- 4.2.5 Other Miscellaneous Machinery
- 4.2.6 Transportation and lifting Machinery
- 4.2.7 Q.C. Machinery and Apparatuses
- 4.3 Composition/Mix Design in Precast construction
- 4.3.1 Cement Required for M25 Grade (in Cubic Meter)
- 4.3.2 Cement Required for M25 Grade (in Kg)
- 4.3.3 Cement Bags Required for M25 Grade
- 4.3.4 Sand Required for M25 Grade (in Cubic Meters)
- 4.3.5 Sand Required for M25 Grade (in Kg)
- 4.3.6 Sand Required for M25 Grade (in cft)
- 4.3.7 Aggregate Required for M25 Grade (in Cubic Meter)
- 4.3.8 Aggregate Required for M25 Grade (in Kg)
- 4.3.9 Aggregate Required for M25 Grade (in cft)
- 4.4 Cost Analysis of Precast Construction (Case Study)
- 5. Pre-Stressed Technology.
- 5.1 Composition/Mix Design in Pre-Stressed Construction
- 5.2 Cost Analysis of Pre-Stressed Construction
- 6. Post-Tension Technology
- 6.1 Composition/Mix Design in Post-Tension Construction
- 6.2 Cost Analysis of Post-Tension Construction
- 7. Conclusions
- 3-D Concrete Printing Technology
- 2. Classification Based on Material
- 3. Classification Based on Technique
- 3.1 Extrusion-Based Technique
- 3.1.1 Contour Crafting
- 3.1.2 Concrete Printing
- 3.1.3 CONPrint3D: Concrete On-Site 3D Printing
- 3.2 Powder-Based Technique
- 3.2.1 D-shape
- 3.2.2 Emerging Objects
- 3.2.3 Powder Based 3D Concrete Printing Using Geopolymer
- 4. Mechanism of 3D Concrete Printing System
- 5. Composition/Mix Design of 3D Concrete Printing
- 5.1 3D-Printable Material Requirements
- 5.2 Material Composition
- 6. Requirements of Concrete for 3D Printing
- 6.1 Extrudability
- 6.2 Buildability
- 6.3 Workability
- 6.4 Open Time
- 6.5 Contact Strength between Layers
- 6.7 Aggregates
- 6.8 Water Cement Ratio
- 6. Challenges for 3D Printable Material in Large Scale Construction
- 7. Advantages of 3D Concrete Printing
- 8. Disadvantages of 3D Concrete Printing
- 9. Conclusions
- Properties and Cost Analysis of 3D Concrete Printing
- 2. Rheological Properties of 3D printable materials
- 2.1 Pumpability of concrete
- 2.2 Extrudability of concrete
- 2.3 Buildability of concrete
- 3. Mechanical properties of 3D printed vs casted steel fiber reinforced concrete
- 4. Types of Reinforcement Strategies for 3D Concrete Printing
- 4.1 Cable Introduction at the Nozzle
- 4.2 Insertion of Reinforcing Elements into the Printed Concrete
- 4.3 Mesh Reinforcement
- 4.4 Printing over Conventional Bars
- 4.5 Use of Printed Reinforcement
- 4.6 Fiber-Reinforced Printable Concrete Mix.
- 4.7 Post-Printed Reinforcement Strategies
- 5. Printability Window
- 6. Cost Analysis of 3D Concrete Printing
- 6.1 Parameter Selection and Strength Requirements of Geopolymer Printable Concrete
- 6.2 Analysis of 3D Concrete Printing Cost Using a Case Study
- Green Concrete
- 2. Composition of Green Concrete
- 2.1 Blast Furnace Slag
- 2.2 Fly Ash
- 2.3 Silica Fume
- 2.4 Recycled Glass
- 2.5 Date Palm Ash
- 3. Cost Analysis of Green concrete and Conventional Concrete
- 3.1 Cost Analysis of Green Concrete with Fly Ash and Bottom Fly Ash with the Cement of 333 kg/m3
- 3.2 Cost Analysis of Green Concrete with Fly Ash, Bottom Ash and Fly Ash Aggregate with a Cement Content of 389 kg/m3
- 4. Conclusions
- Self-Healing Concrete
- 2. Process Involved in Self-Healing Concrete
- 2.1 The Natural Process
- 2.2 The Chemical Self-Healing Process
- 2.3 The Biological Self-Healing Process
- 3. Classification of Self-Healing Concrete
- 3.1 Autogenous Self-Healing Concrete
- 3.2 Autonomous Self-Healing Concrete
- 4. The Environmental Impact of Self-Healing Concrete
- 5. Composition / Mix Design of Self-Healing Concrete
- 6. Mechanism of Self-Healing Concrete
- 7. Properties and Experimental Results
- 7.1 Compressive Strength
- 7.2 Water Absorption
- 7.3 Water Permeability
- 7.4 Other Experimentation Results
- 8. Factors Affecting Self-Healing Concrete
- 8.1 Moisture Content
- 8.2 Crack Width
- 8.3 Time for Hydration
- 8.4 Pressure Applied to Cracks
- 8.5 Water-Cement Ratio
- 9. Advantages of Self-Healing Concrete
- 10. Disadvantages of Self-Healing Concrete
- 11. Cost Analysis of Self-Healing Concrete and Conventional Concrete
- 12. Conclusions
- Conclusions
- 2. Combining 3D-Printing Technology with Green and Self-Healing Concrete.
- 3. Opportunities and Future Implications
- Bibliography
- About the Authors.
- Notes:
- Description based on publisher supplied metadata and other sources.
- ISBN:
- 9781644902158
- 164490215X
- OCLC:
- 1346357954
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