Manageable Structure Materials ?

When discussing “manageable structure materials,” it’s important to consider both the physical properties of the materials and the logistics of handling them. Here’s a breakdown:

Key Considerations:

• Material Properties:
  • Strength-to-weight ratio: How strong is the material relative to its weight? Lighter, strong materials are often easier to manage.
  • Durability: How resistant is the material to weathering, corrosion, and other forms of damage?
  • Workability: How easy is the material to cut, shape, and assemble?
  • Availability: How readily available is the material, and what is its cost?
• Logistical Considerations:
  • Transportation: Can the material be easily transported to the construction site?
  • Storage: Does the material require special storage conditions?
  • Handling: Can the material be easily handled by workers on the construction site?
  • Waste management: how much waste is produced by the material, and how easy is it to dispose of.

Common Structural Materials and Manageability:

• Steel:
  • Pros: High strength, durability.
  • Cons: Heavy, can be susceptible to corrosion, requires specialized tools for cutting and welding.
  • Manageability notes: Steel requires heavy machinery for movement and placement.
• Concrete:
  • Pros: Strong, durable, versatile.
  • Cons: Heavy, requires formwork, curing time.
  • Manageability notes: Ready-mix concrete has made handling easier, but placement still requires careful planning.
• Timber:
  • Pros: Relatively lightweight, easy to work with, renewable.
  • Cons: Susceptible to rot and insects, strength varies.
  • Manageability notes: Timber is generally easy to handle, especially in smaller projects. Engineered lumber increases predictability and strength.
• Masonry (Bricks, Blocks):
  • Pros: Durable, fire-resistant.
  • Cons: Heavy, labor-intensive.
  • Manageability notes: Masonry requires skilled labor for proper installation.
• Modern Composite Materials:
  • Pros: Can be engineered for specific properties, lightweight, strong.
  • Cons: Can be expensive, may require specialized installation.
  • Manageability notes: composite materials are growing in use, and can be very managable, depending on the specific material.

Material Management in Construction:

Beyond the materials themselves, “manageable” also refers to the process of:

• Procuring the right materials, in the right quantities, at the right time.
• Storing materials properly to prevent damage.
• Minimizing waste.
• Using technology to track and manage materials.

In essence, “manageable structure materials” involves a balance of material properties and logistical efficiency.

What is Manageable Structure Materials ?

When we talk about “manageable structure materials,” we’re really talking about a combination of the physical properties of building materials and the logistical ease with which they can be used in construction. It’s not just about the strength of the material, but also about how practical it is to handle, transport, and work with.

Here’s a breakdown:

What “Manageable” Encompasses:

• Ease of Handling:
  • This includes factors like weight, size, and shape. Lighter materials are generally easier to move and position.
  • It also involves how easily the material can be cut, shaped, and fastened.
• Transportation and Storage:
  • Can the material be transported efficiently to the construction site?
  • Does it require specialized storage conditions to prevent damage?
• Workability:
  • How easily can workers manipulate the material on-site?
  • Does it require specialized tools or skills?
• Waste Management:
  • How much waste is generated during construction?
  • How easy is it to dispose of or recycle the material?
• Procurement:
  • How readily available is the material, and what is the cost and lead time.

In essence, “manageable structure materials” means:

• Choosing materials that are practical for the specific construction project.
• Optimizing the logistics of material handling to improve efficiency and reduce costs.

Therefore it is not just the material itself, but the whole process of getting the material to its final placement in a structure.

Who is required Manageable Structure Materials ?

The need for manageable structure materials is relevant to a wide range of stakeholders within the construction industry, and beyond. Here’s a breakdown of who benefits:

Key Stakeholders:

• Construction Companies and Contractors:
  • They are directly responsible for the efficient execution of construction projects. Manageable materials contribute to:
    • Reduced labor costs.
    • Faster construction times.
    • Improved safety on site.
    • Minimized material waste.
• Project Managers:
  • They oversee the entire construction process, and manageable materials help them:
    • Stay within budget.
    • Meet project deadlines.
    • Ensure quality control.
• Architects and Engineers:
  • They design structures, and their material choices impact:
    • Structural integrity.
    • Design aesthetics.
    • Construction feasibility.
• Construction Workers:
  • They handle the materials directly, so manageability affects:
    • Their physical safety.
    • Their productivity.
    • Their overall working conditions.
• Building Owners and Developers:
  • They are concerned with the long-term performance and cost-effectiveness of the structure. Manageable materials contribute to:
    • Reduced maintenance costs.
    • Increased building lifespan.
    • Improved sustainability.
• Supply Chain and Logistics Professionals:
  • Those responsible for the transportation and storage of the materials. Efficient material sizes and weights, and proper packaging effect the cost and effeciency of the supply chain.
• The Environment:
  • Manageable materials often coincide with sustainable practices. Reducing waste, utilizing recycled materials, and minimizing transportation all have positive environmental impacts.

In essence, anyone involved in the design, construction, and maintenance of buildings and infrastructure benefits from the use of manageable structure materials.

When is required Manageable Structure Materials ?

The need for manageable structure materials arises throughout the entire lifecycle of a construction project, but some key phases highlight their importance:

1. During the Design Phase:

• When: Architects and engineers consider material properties and logistics early on.
• Why:
  • To ensure the designed structure is feasible to build.
  • To optimize material usage and minimize waste.
  • To consider the ease of future maintenance and potential modifications.

2. During the Procurement Phase:

• When: When materials are being sourced and purchased.
• Why:
  • To secure materials that are readily available and within budget.
  • To factor in transportation and storage requirements.
  • To establish reliable supply chains.

3. During the Construction Phase:

• When: During the actual building process.
• Why:
  • To maximize worker productivity and safety.
  • To minimize delays caused by material handling issues.
  • To ensure efficient on-site material flow.

4. During the Maintenance and Renovation Phase:

• When: Throughout the lifespan of the structure.
• Why:
  • To facilitate repairs and replacements.
  • To enable cost-effective modifications.
  • To address potential material degradation.

Specific Scenarios Where Manageability Is Crucial:

• Projects in remote or difficult-to-access locations: Where transportation and handling are challenging.
• Projects with tight deadlines: Where efficiency is paramount.
• Projects with limited budgets: Where waste reduction and cost-effectiveness are essential.
• Sustainable construction projects: Where materials with low environmental impact are prioritized.
• Urban construction: where space for material storage and movement is limited.

In essence, manageable structure materials are required at every stage where materials are handled, from initial planning to final disposal.

COURTESY : Structural Engineer Calcs

Where is required Manageable Structure Materials ?

The requirement for manageable structure materials is not limited to a specific location but rather applies to a wide range of construction settings. Here’s a breakdown of where they are needed:

General Construction Sites:

• Urban construction:
  • Limited space for storage and maneuvering necessitates materials that are easily handled and compactly stored.
  • Traffic congestion makes efficient delivery crucial.
• Rural construction:
  • Remote locations can pose challenges for transportation, making lightweight and durable materials preferred.
  • Access to skilled labor may be limited, so materials requiring simple installation are advantageous.
• Suburban construction:
  • Balancing cost-effectiveness with ease of construction is essential.

Specific Project Types:

• Residential construction:
  • From single-family homes to large apartment buildings, manageability impacts construction speed and cost.
• Commercial construction:
  • Office buildings, retail spaces, and industrial facilities require efficient material handling for large-scale projects.
• Infrastructure projects:
  • Bridges, roads, tunnels, and dams require durable and manageable materials for long-term performance.
• Renovation and remodeling projects:
  • Existing structures often present challenges for material access and handling.
• Temporary structures:
  • Event venues, construction scaffolding, and disaster relief shelters require materials that are quick and easy to assemble and disassemble.
• Offshore construction:
  • Oil rigs, wind farms, and other offshore structures need materials that can withstand harsh conditions and are easily handled in challenging environments.
• Underground Construction:
  • Subways, and underground parking garages require materials that can be moved into confined spaces.

Geographic and Environmental Considerations:

• Areas prone to natural disasters:
  • Earthquake-resistant or flood-resistant structures require materials that are both strong and manageable.
• Extreme climates:
  • Materials that can withstand temperature fluctuations, high winds, or heavy precipitation are essential.
• Environmentally sensitive areas:
  • Sustainable materials and construction practices are crucial for minimizing environmental impact.

In essence, the need for manageable structure materials is universal, adapting to the specific demands of each construction project and its location.

How is required Manageable Structure Materials ?

The “how” of requiring manageable structure materials involves a multifaceted approach that spans planning, execution, and ongoing maintenance. Here’s a breakdown of the key aspects:

1. Strategic Planning and Design:

• Material Selection:
  • Architects and engineers must prioritize materials that align with the project’s specific needs, considering factors like:
    • Load-bearing capacity.
    • Environmental conditions.
    • Aesthetic requirements.
    • Long-term durability.
  • Emphasis on materials that are:
    • Lightweight yet strong.
    • Easy to cut, shape, and assemble.
    • Resistant to local climate challenges.
• Design for Efficiency:
  • Designs should optimize material usage, minimizing waste and simplifying installation.
  • Modular designs and prefabricated components can significantly enhance manageability.
  • Consideration of how materials will be moved and placed during construction.

2. Efficient Procurement and Logistics:

• Supply Chain Management:
  • Establishing reliable supply chains to ensure timely delivery of materials.
  • Careful planning of material quantities to avoid shortages or surpluses.
  • Negotiating favorable contracts with suppliers.
• Transportation and Storage:
  • Selecting materials that can be efficiently transported to the construction site.
  • Implementing proper storage procedures to prevent damage and deterioration.
  • Optimizing on-site material flow to minimize handling and movement.

3. Construction Practices:

• Worker Training:
  • Providing workers with the necessary training to handle materials safely and efficiently.
  • Equipping workers with appropriate tools and equipment.
• On-Site Management:
  • Implementing effective material tracking and inventory control systems.
  • Maintaining a clean and organized construction site to facilitate material handling.
  • Using mechanical aids, such as cranes and forklifts, to move heavy or bulky materials.
• Waste Reduction:
  • Implementing strategies to minimize material waste, such as accurate measurement and cutting.
  • Recycling or reusing construction waste whenever possible.

4. Ongoing Maintenance and Adaptation:

• Material Durability:
  • Choosing materials that require minimal maintenance.
  • Implementing regular inspections to identify and address potential problems.
• Adaptability:
  • Selecting materials that allow for future modifications or renovations.
  • Considering the long-term lifecycle of the structure and the potential need for material replacements.

In essence, achieving manageable structure materials requires a holistic approach that integrates careful planning, efficient execution, and a commitment to sustainability.

Case study is Manageable Structure Materials ?

It’s important to understand that “manageable structure materials” isn’t a single, defined material. Rather, it’s a concept that’s applied in various construction projects. Therefore, case studies tend to focus on how specific materials and management practices contribute to improved manageability. Here’s how we can frame some case study scenarios:

Areas Where Case Studies Arise:

• Modular Construction:
  • Scenario: Projects that utilize prefabricated modules (e.g., for housing, offices, or healthcare facilities).
  • Focus:
    • How off-site fabrication reduces on-site labor and waste.
    • The logistical advantages of transporting and assembling pre-built components.
    • The impact on construction speed and overall project costs.
• Lightweight Steel Framing:
  • Scenario: Construction of multi-story buildings or residential structures using lightweight steel framing systems.
  • Focus:
    • The benefits of steel’s strength-to-weight ratio for easier handling and faster erection.
    • Comparisons to traditional concrete or heavy steel construction.
    • The impact on foundation requirements and overall building weight.
• Advanced Composite Materials:
  • Scenario: Projects using fiber-reinforced polymers (FRP) or other composite materials for bridge construction, infrastructure repairs, or unique architectural designs.
  • Focus:
    • The advantages of composites’ high strength, corrosion resistance, and lightweight properties.
    • Case studies of how these materials have enabled innovative designs or extended the lifespan of existing structures.
    • How those materials are implemented in difficult enviroments.
• Logistics Optimization in Large-Scale Projects:
  • Scenario: Major infrastructure projects (e.g., highway construction, airport expansions) that involve the movement of vast quantities of materials.
  • Focus:
    • The use of technology (e.g., GPS tracking, inventory management software) to improve material flow.
    • Strategies for minimizing transportation costs and on-site congestion.
    • The impact of effective logistics on project timelines and budgets.
• Sustainable Material Use:
  • Scenario: Construction projects that prioritize the use of recycled materials, renewable resources (e.g., engineered timber), or locally sourced materials.
  • Focus:
    • The environmental benefits of sustainable material choices.
    • Case studies of how these materials can be integrated into construction projects without compromising structural integrity.
    • How waste reduction is achieved.

Key Elements of Such Case Studies:

• Problem: The challenges faced in the construction project (e.g., tight deadlines, limited space, environmental constraints).
• Solution: The specific materials and management practices that were implemented.
• Results: The measurable outcomes (e.g., reduced construction time, cost savings, improved safety, reduced environmental impact).

By examining these kinds of real world examples, it is possible to see the real world impact of the principles of manageable structural materials.

COURTESY : Next Generation Science

White paper on Manageable Structure Materials ?

White Paper: Optimizing Construction Efficiency Through Manageable Structure Materials

Executive Summary:

The construction industry faces increasing pressure to deliver projects faster, more cost-effectively, and with a reduced environmental footprint. This white paper explores the concept of “manageable structure materials,” a holistic approach that prioritizes material properties and logistical efficiency. By understanding the key considerations and implementing best practices, stakeholders can significantly enhance project outcomes.

1. Introduction:

Traditional construction practices often prioritize material strength and durability, sometimes overlooking the practicalities of handling, transportation, and installation. “Manageable structure materials” shifts this paradigm, focusing on materials and methods that streamline the entire construction process. This paper aims to define the core principles of manageability and outline strategies for its successful implementation.

2. Defining Manageable Structure Materials:

Manageability encompasses the ease with which materials can be:

• Handled: Weight, size, shape, and ease of manipulation.
• Transported and Stored: Logistics, accessibility, and storage requirements.
• Worked With: Cutting, shaping, fastening, and assembly.
• Managed as Waste: Waste reduction, recycling, and disposal.
• Procured: Availability, cost, and lead time.

3. Key Considerations for Material Selection:

• Strength-to-Weight Ratio: Prioritize lightweight materials with high strength.
• Durability and Longevity: Select materials that withstand environmental conditions and require minimal maintenance.
• Workability and Ease of Installation: Choose materials that can be easily manipulated on-site.
• Sustainability: Opt for recycled, renewable, or locally sourced materials.
• Cost-Effectiveness: Balance material costs with long-term performance and logistical savings.

4. Strategies for Enhancing Manageability:

• Modular Construction and Prefabrication:
  • Off-site fabrication reduces on-site labor, waste, and construction time.
  • Modular designs simplify assembly and improve quality control.
• Lightweight Framing Systems:
  • Steel, timber, and composite framing systems offer high strength with reduced weight.
  • Faster erection and reduced foundation requirements.
• Advanced Composite Materials:
  • FRP and other composites offer exceptional strength, corrosion resistance, and lightweight properties.
  • Ideal for infrastructure projects and challenging environments.
• Logistics Optimization:
  • Implement technology-driven inventory management and tracking systems.
  • Optimize transportation routes and schedules.
  • Establish efficient on-site material flow.
• Sustainable Material Management:
  • Prioritize recycled and renewable materials.
  • Implement waste reduction and recycling programs.
  • Utilize locally sourced materials to minimize transportation impacts.
• Digitalization:
  • BIM (Building information modeling) to plan material placement, and reduce waste.
  • Digital twins to plan complex logistical operations.

5. Benefits of Manageable Structure Materials:

• Reduced Construction Time and Costs: Streamlined logistics and efficient installation.
• Improved Safety: Reduced handling of heavy materials and safer on-site operations.
• Enhanced Sustainability: Reduced waste and environmental impact.
• Increased Productivity: Efficient material flow and simplified installation.
• Improved Project Quality: Consistent material properties and controlled assembly.

6. Case Studies (Examples):

• Modular housing projects demonstrating rapid deployment and cost savings.
• Infrastructure projects utilizing FRP composites for enhanced durability and reduced maintenance.
• Large-scale construction projects implementing advanced logistics optimization.

7. Conclusion:

The adoption of manageable structure materials is essential for the future of the construction industry. By prioritizing material properties and logistical efficiency, stakeholders can achieve significant improvements in project outcomes. This white paper serves as a guide for implementing best practices and fostering innovation in material management.

8. Recommendations:

• Promote collaboration between architects, engineers, contractors, and material suppliers.
• Invest in research and development of sustainable and manageable materials.
• Implement training programs for construction workers on efficient material handling and installation.
• Utilize digital technologies to optimize material management and logistics.
• Encourage the use of standardized modular components.

9. Future Outlook:

The ongoing development of advanced materials and digital technologies will further enhance the manageability of construction projects. The industry must embrace innovation and adopt a holistic approach to material management to meet the challenges of the future.

Industrial application of Manageable Structure Materials ?

The concept of “manageable structure materials” has broad industrial applications, spanning various sectors. Here’s how it manifests in different industrial settings:

1. Manufacturing:

• Automotive Industry:
  • Use of lightweight steel and aluminum alloys for vehicle frames to improve fuel efficiency and ease of assembly.
  • Implementation of conveyor systems and automated guided vehicles (AGVs) for efficient material flow along assembly lines.
  • Utilizing composite materials for car body parts to reduce weight and enhance durability.
• Aerospace Industry:
  • Extensive use of advanced composite materials (carbon fiber, etc.) for aircraft structures to minimize weight and maximize strength.
  • Modular design and prefabrication of aircraft components for faster assembly and maintenance.
  • Use of advanced alloys that are both strong, and workable.
• Industrial Warehousing:
  • Implementation of automated storage and retrieval systems (AS/RS) for efficient inventory management.
  • Use of modular shelving and racking systems for flexible storage configurations.
  • Use of AGVs and robotic systems for material handling.

2. Construction:

• Prefabricated Buildings:
  • Construction of modular homes and commercial buildings using prefabricated components.
  • Use of lightweight steel framing and engineered lumber for faster and easier construction.
  • On site use of cranes and other heavy machinery to move large pre fabricated sections.
• Infrastructure Projects:
  • Use of precast concrete components for bridges and tunnels to reduce on-site construction time.
  • Implementation of advanced composite materials for bridge repairs and reinforcement.
  • Optimized logistics for the delivery of bulk materials like aggregate and asphalt.
• Industrial Plants:
  • The construction of industrial plants require materials that are resistant to the chemicals, and extreme temperatures that may be present. This requires careful material selection, and placement.

3. Logistics and Supply Chain:

• Material Handling Equipment:
  • Development of lightweight and ergonomic material handling equipment to reduce worker strain.
  • Use of automated systems for sorting, packaging, and shipping materials.
  • Optimization of warehouse layouts for efficient material flow.
• Packaging Industry:
  • Development of lightweight and durable packaging materials to reduce transportation costs.
  • Use of recyclable and biodegradable packaging materials to minimize environmental impact.

Key Trends:

• Automation: Increased use of robotic systems and AGVs for material handling.
• Sustainability: Growing emphasis on using recycled and renewable materials.
• Digitalization: Implementation of digital technologies for material tracking and inventory management.
• Modularization: Increased use of prefabricated components to streamline construction and manufacturing processes.

By adopting manageable structure materials and related technologies, industries can enhance efficiency, reduce costs, and improve sustainability.

Research and development of Manageable Structure Materials ?

Research and development (R&D) in the field of manageable structure materials is a dynamic and crucial area, driving innovation across various industries. Here’s a look at some key focus areas:

1. Advanced Material Development:

• Lightweight, High-Strength Materials:
  • Research into new alloys, composite materials (like fiber-reinforced polymers), and engineered wood products that offer superior strength-to-weight ratios.
  • Nanomaterials: Exploring the use of nanoparticles to enhance the properties of existing materials, such as increasing strength, durability, and resistance to corrosion.
• Sustainable Materials:
  • Developing bio-based materials from renewable resources, such as bamboo, hemp, and mycelium.
  • Improving recycling and reuse processes for construction and industrial materials.
  • Research into materials with lower embodied carbon.
• Smart Materials:
  • Developing materials with integrated sensors that can monitor structural health and provide real-time data.
  • Exploring self-healing materials that can repair damage automatically.

2. Construction and Manufacturing Technologies:

• Modular Construction and Prefabrication:
  • Developing standardized modular components that can be easily assembled on-site.
  • Improving automation and robotics in prefabrication processes.
• Additive Manufacturing (3D Printing):
  • Exploring the use of 3D printing for on-demand fabrication of complex structural components.
  • Developing new 3D-printable materials with enhanced properties.
• Digitalization and Automation:
  • Implementing Building Information Modeling (BIM) and digital twin technologies to optimize material usage and logistics.
  • Developing automated systems for material handling and installation.

3. Logistics and Supply Chain Optimization:

• Advanced Tracking and Monitoring:
  • Implementing IoT (Internet of Things) sensors and GPS tracking to monitor material location and condition.
  • Developing AI-powered systems for supply chain optimization.
• Efficient Transportation and Storage:
  • Researching new transportation methods to reduce costs and environmental impact.
  • Developing innovative storage solutions to minimize material damage and waste.

Key Drivers of R&D:

• Sustainability: The growing need to reduce the environmental impact of construction and manufacturing.
• Efficiency: The desire to improve productivity and reduce costs.
• Safety: The need to create safer working environments.
• Resilience: The demand for structures that can withstand extreme weather events and other hazards.

R&D in manageable structure materials is a multidisciplinary effort, involving materials scientists, engineers, architects, and technology experts. By continuing to invest in these areas, we can create a more sustainable, efficient, and resilient built environment.

COURTESY : SliderBank

References

1. ^ “building” def. 2 and 4, “material” def. 1. Oxford English Dictionary Second Edition on CD-ROM (v. 4.0)© Oxford University Press 2009
2. ^ Jump up to:^a b Bennai, Fares (28 June 2017). Étude des mécanismes de transferts couplés de chaleur et d’humidité dans les matériaux poreux de construction en régime insaturé (Thesis) (in French).^{[page needed]}
3. ^ Othmen, Inès; Poullain, Philippe; Leklou, Ali-Nordine (June 2014). “Etude numérique des techniques d’isolation : application à la réhabilitation du bâti ancien en tuffeau”. 32èmes Rencontres Universitaires de Génie Civil.
4. ^ Bourbia, S.; Kazeoui, H.; Belarbi, R. (2023). “A review on recent research on bio-based building materials and their applications”. Materials for Renewable and Sustainable Energy. 12 (2): 117–139. doi:10.1007/s40243-023-00234-7.
5. ^ Nabokov, Peter; Easton, Robert (1989). Native American Architecture. Oxford University Press. p. 16. ISBN 978-0-19-506665-4.
6. ^ Kent, Susan (1993). Domestic Architecture and the Use of Space: An Interdisciplinary Cross-Cultural Study. Cambridge University Press. p. 131. ISBN 978-0-521-44577-1.
7. ^ Shaffer, Gary D. (Spring 1993). “An Archaeomagnetic Study of a Wattle and Daub Building Collapse”. Journal of Field Archaeology. 20 (1): 59–75. doi:10.2307/530354. JSTOR 530354.
8. ^ Lyon, George Francis (1824). The Private Journal of Captain G.F. Lyon, of H.M.S. Hecla: During the Recent Voyage of Discovery Under Captain Parry. J. Murray. pp. 280–281. OCLC 367961511.
9. ^ Hall, Michael; Saarinen, Jarkko (2010). Tourism and Change in Polar Regions: Climate, Environments and Experiences. Routledge. p. 30. ISBN 978-1-136-97199-0.
10. ^ Jump up to:^a b McHenry, Paul Graham (1984). Adobe and Rammed Earth Buildings: Design and Construction. Wiley. p. 104. ISBN 978-0-471-87677-9.
11. ^ Smith, Michael G. (2002). “Cob Building, Ancient and Modern”. In Kennedy, Joseph F.; Wanek, Catherine; Smith, Michael G. (eds.). The Art of Natural Building: Design, Construction, Resources. New Society Publishers. pp. 132–133. ISBN 978-0-86571-433-5.
12. ^ [1] Earliest Chinese building brick appeared in Xi’an (中國最早磚類建材在西安現身)]. takungpao.com (2010-1-28)
13. ^ Zoya Kpamma, Z. Mohammed Kamil, K. Adinkrah-Appiah, “Making Wall Construction Process Lean:The Interlocking Blocksystem as a Toole” [sic], International Conference on Infrastructural Development In Africa (ICIDA), KNUST, Kumasi, Ghana, March 2012. https://www.academia.edu/2647016/MAKING_WALL_CONSTRUCTION_PROCESS_LEAN_THE_INTERLOCKING_BLOCK_SYSTEM_AS_A_TOOL accessed 12/11/2013
14. ^ “Thermal mass”. Your Home. Australian Government. Retrieved 2020-08-17.
15. ^ [2] Archived 2013-04-02 at the Wayback Machine History of bricks wienerberger.com
16. ^ “Top 5 Reasons Why Bricks Are The Most Popular Building Material”. primedb.co. May 11, 2017.
17. ^ Sandermann, Wilhelm; Kohler, Roland (January 1964). “Über eine kurze Eignungsprüfung von Hölzern für zementgebundene Werkstoffe – Studien über mineralgebundene Holzwerkstoffe, VI. Mitteilung”. Holzforschung. 18 (1–2): 53–59. doi:10.1515/hfsg.1964.18.1-2.53.
18. ^ Weatherwax, R C; Tarkow, H (1964). “Effect of Wood on Setting of Portland Cement”. Forest Products Journal. 14: 567–568.
19. ^ Hachmi, M.; Moslemi, A. A.; Campbell, A. G. (October 1990). “A new technique to classify the compatibility of wood with cement”. Wood Science and Technology. 24 (4): 345–354. doi:10.1007/BF00227055.
20. ^ Lee, A. W. C; Hong, Zhongli (1986). “Compressive strength of cylindrical samples as an indicator of wood-cement compatibility”. Forest Products Journal. 36 (11–12): 87–90. INIST 8084764.
21. ^ Demirbaş, A; Aslan, A (August 1998). “Effects of ground hazelnut shell, wood, and tea waste on the mechanical properties of cement22Communicated by A.K. Chatterjee”. Cement and Concrete Research. 28 (8): 1101–1104. doi:10.1016/S0008-8846(98)00064-7.
22. ^ Ahn, W.Y.; Moslemi, A.A. “SEM examination of wood-Portland cement bonds”. Wood Science. 13 (2): 77–82.
23. ^ Karade, S. R.; Irle, M.; Maher, K. (30 October 2003). “Assessment of Wood-Cement Compatibility: A New Approach”. Holzforschung. 57 (6): 672–680. doi:10.1515/HF.2003.101.
24. ^ Li, Juan; Kasal, Bohumil (September 2022). “The immediate and short-term degradation of the wood surface in a cement environment measured by AFM”. Materials and Structures. 55 (7). doi:10.1617/s11527-022-01988-8.
25. ^ Li, Juan; Kasal, Bohumil (July 2023). “Degradation Mechanism of the Wood-Cell Wall Surface in a Cement Environment Measured by Atomic Force Microscopy”. Journal of Materials in Civil Engineering. 35 (7). doi:10.1061/JMCEE7.MTENG-14910.
26. ^ “The Advantages of ETFE Fluoropolymer Tubing”. Fluorotherm. April 1, 2015.
27. ^ Jump up to:^a b Smethurst, Tom (18 May 2023). “Why we must limit use of construction plastics”. RICS. Retrieved 5 Dec 2024.
28. ^ Jump up to:^a b c Hernandez, German; Low, Joanne; Nand, Ashveen; Bu, Alex; Wallis, Shannon L; Kestle, Linda; Berry, Terri-Ann (13 Jun 2022). “Quantifying and managing plastic waste generated from building construction in Auckland, New Zealand”. Waste Management & Research: The Journal for a Sustainable Circular Economy. 41 (1). SAGE Publications: 205–213. doi:10.1177/0734242×221105425. hdl:10652/5874. ISSN 0734-242X.
29. ^ “Rapid prototyping quickly becoming the standard in construction”. The Manufacturer. Retrieved 2021-09-30.
30. ^ “Global Status Report 2017”. www.worldgbc.org. World Green Building Council. Retrieved 2019-03-12.
31. ^ Dixit, Manish K.; Culp, Charles H.; Fernandez-Solis, Jose L. (3 February 2015). “Embodied Energy of Construction Materials: Integrating Human and Capital Energy into an IO-Based Hybrid Model”. Environmental Science & Technology. 49 (3): 1936–1945. Bibcode:2015EnST…49.1936D. doi:10.1021/es503896v. PMID 25561008.
32.  Nawy, Edward G. (1989). Prestressed Concrete. Prentice Hall. ISBN 0-13-698375-8.
33. ^ Nilson, Arthur H. (1987). Design of Prestressed Concrete. John Wiley & Sons. ISBN 0-471-83072-0.

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